source: nikanabo/current/xdelta/diy/xdelta3.c@ 986

Last change on this file since 986 was 185, checked in by geyser, 17 years ago
File size: 149.4 KB
Line 
1/* xdelta 3 - delta compression tools and library
2 * Copyright (C) 2001, 2003, 2004, 2005, 2006. Joshua P. MacDonald
3 *
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
8 *
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write to the Free Software
16 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
17
18 -------------------------------------------------------------------
19
20 Xdelta 3
21
22 The goal of this library is to to implement both the (stand-alone)
23 data-compression and delta-compression aspects of VCDIFF encoding, and
24 to support a programming interface that works like Zlib
25 (http://www.gzip.org/zlib.html). See RFC3284: The VCDIFF Generic
26 Differencing and Compression Data Format.
27
28 VCDIFF is a unified encoding that combines data-compression and
29 delta-encoding ("differencing").
30
31 VCDIFF has a detailed byte-code instruction set with many features.
32 The instruction format supports an immediate size operand for small
33 COPYs and ADDs (e.g., under 18 bytes). There are also instruction
34 "modes", which are used to compress COPY addresses by using two
35 address caches. An instruction mode refers to slots in the NEAR
36 and SAME caches for recent addresses. NEAR remembers the
37 previous 4 (by default) COPY addresses, and SAME catches
38 frequent re-uses of the same address using a 3-way (by default)
39 256-entry associative cache of [ADDR mod 256], the encoded byte.
40 A hit in the NEAR/SAME cache requires 0/1 ADDR bytes.
41
42 VCDIFF has a default instruction table, but an alternate
43 instruction tables may themselves be be delta-compressed and
44 included in the encoding header. This allows even more freedom.
45 There are 9 instruction modes in the default code table, 4 near, 3
46 same, VCD_SELF (absolute encoding) and VCD_HERE (relative to the
47 current position).
48
49 ----------------------------------------------------------------------
50
51 Algorithms
52
53 Aside from the details of encoding and decoding, there are a bunch
54 of algorithms needed.
55
56 1. STRING-MATCH. A two-level fingerprinting approach is used. A
57 single loop computes the two checksums -- small and large -- at
58 successive offsets in the TARGET file. The large checksum is more
59 accurate and is used to discover SOURCE matches, which are
60 potentially very long. The small checksum is used to discover
61 copies within the TARGET. Small matching, which is more expensive,
62 usually dominates the large STRING-MATCH costs in this code - the
63 more exhaustive the search, the better the results. Either of the
64 two string-matching mechanisms may be disabled.
65
66 2. INSTRUCTION SELECTION. The IOPT buffer here represents a queue
67 used to store overlapping copy instructions. There are two possible
68 optimizations that go beyond a greedy search. Both of these fall
69 into the category of "non-greedy matching" optimizations.
70
71 The first optimization stems from backward SOURCE-COPY matching.
72 When a new SOURCE-COPY instruction covers a previous instruction in
73 the target completely, it is erased from the queue. Randal Burns
74 originally analyzed these algorithms and did a lot of related work
75 (\cite the 1.5-pass algorithm).
76
77 The second optimization comes by the encoding of common very-small
78 COPY and ADD instructions, for which there are special DOUBLE-code
79 instructions, which code two instructions in a single byte.
80
81 The cost of bad instruction-selection overhead is relatively high
82 for data-compression, relative to delta-compression, so this second
83 optimization is fairly important. With "lazy" matching (the name
84 used in Zlib for a similar optimization), the string-match
85 algorithm searches after a match for potential overlapping copy
86 instructions. In Xdelta and by default, VCDIFF, the minimum match
87 size is 4 bytes, whereas Zlib searches with a 3-byte minimum. This
88 feature, combined with double instructions, provides a nice
89 challenge. Search in this file for "black magic", a heuristic.
90
91 3. STREAM ALIGNMENT. Stream alignment is needed to compress large
92 inputs in constant space. See xd3_srcwin_move_point().
93
94 4. WINDOW SELECTION. When the IOPT buffer flushes, in the first call
95 to xd3_iopt_finish_encoding containing any kind of copy instruction,
96 the parameters of the source window must be decided: the offset into
97 the source and the length of the window. Since the IOPT buffer is
98 finite, the program may be forced to fix these values before knowing
99 the best offset/length.
100
101 5. SECONDARY COMPRESSION. VCDIFF supports a secondary encoding to
102 be applied to the individual sections of the data format, which are
103 ADDRess, INSTruction, and DATA. Several secondary compressor
104 variations are implemented here, although none is standardized yet.
105
106 One is an adaptive huffman algorithm -- the FGK algorithm (Faller,
107 Gallager, and Knuth, 1985). This compressor is extremely slow.
108
109 The other is a simple static Huffman routine, which is the base
110 case of a semi-adaptive scheme published by D.J. Wheeler and first
111 widely used in bzip2 (by Julian Seward). This is a very
112 interesting algorithm, originally published in nearly cryptic form
113 by D.J. Wheeler. !!!NOTE!!! Because these are not standardized,
114 secondary compression remains off by default.
115 ftp://ftp.cl.cam.ac.uk/users/djw3/bred3.{c,ps}
116 --------------------------------------------------------------------
117
118 Other Features
119
120 1. USER CONVENIENCE
121
122 For user convenience, it is essential to recognize Gzip-compressed
123 files and automatically Gzip-decompress them prior to
124 delta-compression (or else no delta-compression will be achieved
125 unless the user manually decompresses the inputs). The compressed
126 represention competes with Xdelta, and this must be hidden from the
127 command-line user interface. The Xdelta-1.x encoding was simple, not
128 compressed itself, so Xdelta-1.x uses Zlib internally to compress the
129 representation.
130
131 This implementation supports external compression, which implements
132 the necessary fork() and pipe() mechanics. There is a tricky step
133 involved to support automatic detection of a compressed input in a
134 non-seekable input. First you read a bit of the input to detect
135 magic headers. When a compressed format is recognized, exec() the
136 external compression program and create a second child process to
137 copy the original input stream. [Footnote: There is a difficulty
138 related to using Gzip externally. It is not possible to decompress
139 and recompress a Gzip file transparently. If FILE.GZ had a
140 cryptographic signature, then, after: (1) Gzip-decompression, (2)
141 Xdelta-encoding, (3) Gzip-compression the signature could be
142 broken. The only way to solve this problem is to guess at Gzip's
143 compression level or control it by other means. I recommend that
144 specific implementations of any compression scheme store
145 information needed to exactly re-compress the input, that way
146 external compression is transparent - however, this won't happen
147 here until it has stabilized.]
148
149 2. APPLICATION-HEADER
150
151 This feature was introduced in RFC3284. It allows any application
152 to include a header within the VCDIFF file format. This allows
153 general inter-application data exchange with support for
154 application-specific extensions to communicate metadata.
155
156 3. VCDIFF CHECKSUM
157
158 An optional checksum value is included with each window, which can
159 be used to validate the final result. This verifies the correct source
160 file was used for decompression as well as the obvious advantage:
161 checking the implementation (and underlying) correctness.
162
163 4. LIGHT WEIGHT
164
165 The code makes efforts to avoid copying data more than necessary.
166 The code delays many initialization tasks until the first use, it
167 optimizes for identical (perfectly matching) inputs. It does not
168 compute any checksums until the first lookup misses. Memory usage
169 is reduced. String-matching is templatized (by slightly gross use
170 of CPP) to hard-code alternative compile-time defaults. The code
171 has few outside dependencies.
172 ----------------------------------------------------------------------
173
174 The default rfc3284 instruction table:
175 (see RFC for the explanation)
176
177 TYPE SIZE MODE TYPE SIZE MODE INDEX
178 --------------------------------------------------------------------
179 1. Run 0 0 Noop 0 0 0
180 2. Add 0, [1,17] 0 Noop 0 0 [1,18]
181 3. Copy 0, [4,18] 0 Noop 0 0 [19,34]
182 4. Copy 0, [4,18] 1 Noop 0 0 [35,50]
183 5. Copy 0, [4,18] 2 Noop 0 0 [51,66]
184 6. Copy 0, [4,18] 3 Noop 0 0 [67,82]
185 7. Copy 0, [4,18] 4 Noop 0 0 [83,98]
186 8. Copy 0, [4,18] 5 Noop 0 0 [99,114]
187 9. Copy 0, [4,18] 6 Noop 0 0 [115,130]
188 10. Copy 0, [4,18] 7 Noop 0 0 [131,146]
189 11. Copy 0, [4,18] 8 Noop 0 0 [147,162]
190 12. Add [1,4] 0 Copy [4,6] 0 [163,174]
191 13. Add [1,4] 0 Copy [4,6] 1 [175,186]
192 14. Add [1,4] 0 Copy [4,6] 2 [187,198]
193 15. Add [1,4] 0 Copy [4,6] 3 [199,210]
194 16. Add [1,4] 0 Copy [4,6] 4 [211,222]
195 17. Add [1,4] 0 Copy [4,6] 5 [223,234]
196 18. Add [1,4] 0 Copy 4 6 [235,238]
197 19. Add [1,4] 0 Copy 4 7 [239,242]
198 20. Add [1,4] 0 Copy 4 8 [243,246]
199 21. Copy 4 [0,8] Add 1 0 [247,255]
200 --------------------------------------------------------------------
201
202 Reading the source: Overview
203
204 This file includes itself in several passes to macro-expand certain
205 sections with variable forms. Just read ahead, there's only a
206 little confusion. I know this sounds ugly, but hard-coding some of
207 the string-matching parameters results in a 10-15% increase in
208 string-match performance. The only time this hurts is when you have
209 unbalanced #if/endifs.
210
211 A single compilation unit tames the Makefile. In short, this is to
212 allow the above-described hack without an explodingMakefile. The
213 single compilation unit includes the core library features,
214 configurable string-match templates, optional main() command-line
215 tool, misc optional features, and a regression test. Features are
216 controled with CPP #defines, see Makefile.am.
217
218 The initial __XDELTA3_C_HEADER_PASS__ starts first, the INLINE and
219 TEMPLATE sections follow. Easy stuff first, hard stuff last.
220
221 Optional features include:
222
223 xdelta3-main.h The command-line interface, external compression
224 support, POSIX-specific, info & VCDIFF-debug tools.
225 xdelta3-second.h The common secondary compression routines.
226 xdelta3-decoder.h All decoding routines.
227 xdelta3-djw.h The semi-adaptive huffman secondary encoder.
228 xdelta3-fgk.h The adaptive huffman secondary encoder.
229 xdelta3-test.h The unit test covers major algorithms,
230 encoding and decoding. There are single-bit
231 error decoding tests. There are 32/64-bit file size
232 boundary tests. There are command-line tests.
233 There are compression tests. There are external
234 compression tests. There are string-matching tests.
235 There should be more tests...
236
237 Additional headers include:
238
239 xdelta3.h The public header file.
240 xdelta3-cfgs.h The default settings for default, built-in
241 encoders. These are hard-coded at
242 compile-time. There is also a single
243 soft-coded string matcher for experimenting
244 with arbitrary values.
245 xdelta3-list.h A cyclic list template
246
247 Misc little debug utilities:
248
249 badcopy.c Randomly modifies an input file based on two
250 parameters: (1) the probability that a byte in
251 the file is replaced with a pseudo-random value,
252 and (2) the mean change size. Changes are
253 generated using an expoential distribution
254 which approximates the expected error_prob
255 distribution.
256 --------------------------------------------------------------------
257
258 This file itself is unusually large. I hope to defend this layout
259 with lots of comments. Everything in this file is related to
260 encoding and decoding. I like it all together - the template stuff
261 is just a hack. */
262
263#ifndef __XDELTA3_C_HEADER_PASS__
264#define __XDELTA3_C_HEADER_PASS__
265
266#include <errno.h>
267#include <string.h>
268
269#include "xdelta3.h"
270
271/******************************************************************************************
272 STATIC CONFIGURATION
273 ******************************************************************************************/
274
275#ifndef XD3_MAIN /* the main application */
276#define XD3_MAIN 0
277#endif
278
279#ifndef VCDIFF_TOOLS
280#define VCDIFF_TOOLS XD3_MAIN
281#endif
282
283#ifndef SECONDARY_FGK /* one from the algorithm preservation department: */
284#define SECONDARY_FGK 0 /* adaptive Huffman routines */
285#endif
286
287#ifndef SECONDARY_DJW /* semi-adaptive/static Huffman for the eventual */
288#define SECONDARY_DJW 0 /* standardization, off by default until such time. */
289#endif
290
291#ifndef GENERIC_ENCODE_TABLES /* These three are the RFC-spec'd app-specific */
292#define GENERIC_ENCODE_TABLES 0 /* code features. This is tested but not recommended */
293#endif /* unless there's a real application. */
294#ifndef GENERIC_ENCODE_TABLES_COMPUTE
295#define GENERIC_ENCODE_TABLES_COMPUTE 0
296#endif
297#ifndef GENERIC_ENCODE_TABLES_COMPUTE_PRINT
298#define GENERIC_ENCODE_TABLES_COMPUTE_PRINT 0
299#endif
300
301#if XD3_USE_LARGEFILE64 /* How does everyone else do this? */
302#ifndef WIN32
303#define Q "q"
304#else
305#define Q "I64"
306#endif
307#else
308#define Q
309#endif
310
311#if XD3_ENCODER
312#define IF_ENCODER(x) x
313#else
314#define IF_ENCODER(x)
315#endif
316
317/******************************************************************************************/
318
319typedef enum {
320
321 /* header indicator bits */
322 VCD_SECONDARY = (1 << 0), /* uses secondary compressor */
323 VCD_CODETABLE = (1 << 1), /* supplies code table data */
324 VCD_APPHEADER = (1 << 2), /* supplies application data */
325 VCD_INVHDR = ~7U,
326
327 /* window indicator bits */
328 VCD_SOURCE = (1 << 0), /* copy window in source file */
329 VCD_TARGET = (1 << 1), /* copy window in target file */
330 VCD_ADLER32 = (1 << 2), /* has adler32 checksum */
331 VCD_INVWIN = ~7U,
332
333 VCD_SRCORTGT = VCD_SOURCE | VCD_TARGET,
334
335 /* delta indicator bits */
336 VCD_DATACOMP = (1 << 0),
337 VCD_INSTCOMP = (1 << 1),
338 VCD_ADDRCOMP = (1 << 2),
339 VCD_INVDEL = ~0x7U,
340
341} xd3_indicator;
342
343typedef enum {
344 VCD_DJW_ID = 1,
345 VCD_FGK_ID = 16, /* !!!Note: these are not a standard IANA-allocated ID!!! */
346} xd3_secondary_ids;
347
348typedef enum {
349 SEC_NOFLAGS = 0,
350 SEC_COUNT_FREQS = (1 << 0), /* OPT: Not implemented: Could eliminate first pass of Huffman... */
351} xd3_secondary_flags;
352
353typedef enum {
354 DATA_SECTION, /* These indicate which section to the secondary compressor. */
355 INST_SECTION, /* The header section is not compressed, therefore not listed here. */
356 ADDR_SECTION,
357} xd3_section_type;
358
359typedef enum
360{
361 XD3_NOOP = 0,
362 XD3_ADD = 1,
363 XD3_RUN = 2,
364 XD3_CPY = 3, /* XD3_CPY rtypes are represented as (XD3_CPY + copy-mode value) */
365} xd3_rtype;
366
367/******************************************************************************************/
368
369#include "xdelta3-list.h"
370
371XD3_MAKELIST(xd3_rlist, xd3_rinst, link);
372
373/******************************************************************************************/
374
375#ifndef unlikely /* The unlikely macro - any good? */
376#if defined(__GNUC__) && __GNUC__ >= 3
377#define unlikely(x) __builtin_expect((x),0)
378#define likely(x) __builtin_expect((x),1)
379#else
380#define unlikely(x) (x)
381#define likely(x) (x)
382#endif
383#endif
384
385#define SECONDARY_MIN_SAVINGS 2 /* Secondary compression has to save at least this many bytes. */
386#define SECONDARY_MIN_INPUT 10 /* Secondary compression needs at least this many bytes. */
387
388#define VCDIFF_MAGIC1 0xd6 /* 1st file byte */
389#define VCDIFF_MAGIC2 0xc3 /* 2nd file byte */
390#define VCDIFF_MAGIC3 0xc4 /* 3rd file byte */
391#define VCDIFF_VERSION 0x00 /* 4th file byte */
392
393#define VCD_SELF 0 /* 1st address mode */
394#define VCD_HERE 1 /* 2nd address mode */
395
396#define CODE_TABLE_STRING_SIZE (6 * 256) /* Should fit a code table string. */
397#define CODE_TABLE_VCDIFF_SIZE (6 * 256) /* Should fit a compressed code table string */
398
399#define SECONDARY_ANY (SECONDARY_DJW || SECONDARY_FGK) /* True if any secondary compressor is used. */
400
401#define ALPHABET_SIZE 256 /* Used in test code--size of the secondary compressor alphabet. */
402
403#define HASH_PRIME 0 /* Old hashing experiments */
404#define HASH_PERMUTE 1
405#define ARITH_SMALL_CKSUM 1
406
407#define HASH_CKOFFSET 1U /* Table entries distinguish "no-entry" from offset 0 using this offset. */
408
409#define MIN_SMALL_LOOK 2U /* Match-optimization stuff. */
410#define MIN_LARGE_LOOK 2U
411#define MIN_MATCH_OFFSET 1U
412#define MAX_MATCH_SPLIT 18U /* VCDIFF code table: 18 is the default limit for direct-coded ADD sizes */
413
414#define LEAST_MATCH_INCR 0 /* The least number of bytes an overlapping match must beat
415 * the preceding match by. This is a bias for the lazy
416 * match optimization. A non-zero value means that an
417 * adjacent match has to be better by more than the step
418 * between them. 0. */
419
420#define MIN_MATCH 4U /* VCDIFF code table: MIN_MATCH=4 */
421#define MIN_ADD 1U /* 1 */
422#define MIN_RUN 8U /* The shortest run, if it is shorter than this an immediate
423 * add/copy will be just as good. ADD1/COPY6 = 1I+1D+1A bytes,
424 * RUN18 = 1I+1D+1A. */
425
426#define MAX_MODES 9 /* Maximum number of nodes used for compression--does not limit decompression. */
427
428#define ENC_SECTS 4 /* Number of separate output sections. */
429
430#define HDR_TAIL(s) (stream->enc_tails[0])
431#define DATA_TAIL(s) (stream->enc_tails[1])
432#define INST_TAIL(s) (stream->enc_tails[2])
433#define ADDR_TAIL(s) (stream->enc_tails[3])
434
435#define HDR_HEAD(s) (stream->enc_heads[0])
436#define DATA_HEAD(s) (stream->enc_heads[1])
437#define INST_HEAD(s) (stream->enc_heads[2])
438#define ADDR_HEAD(s) (stream->enc_heads[3])
439
440#define SIZEOF_ARRAY(x) (sizeof(x) / sizeof(x[0]))
441
442#define TOTAL_MODES(x) (2+(x)->acache.s_same+(x)->acache.s_near)
443
444/* Template instances. */
445#if XD3_BUILD_SLOW
446#define IF_BUILD_SLOW(x) x
447#else
448#define IF_BUILD_SLOW(x)
449#endif
450#if XD3_BUILD_FAST
451#define IF_BUILD_FAST(x) x
452#else
453#define IF_BUILD_FAST(x)
454#endif
455#if XD3_BUILD_FASTEST
456#define IF_BUILD_FASTEST(x) x
457#else
458#define IF_BUILD_FASTEST(x)
459#endif
460#if XD3_BUILD_SOFT
461#define IF_BUILD_SOFT(x) x
462#else
463#define IF_BUILD_SOFT(x)
464#endif
465#if XD3_BUILD_DEFAULT
466#define IF_BUILD_DEFAULT(x) x
467#else
468#define IF_BUILD_DEFAULT(x)
469#endif
470
471IF_BUILD_SOFT(static const xd3_smatcher __smatcher_soft;)
472IF_BUILD_FAST(static const xd3_smatcher __smatcher_fast;)
473IF_BUILD_SLOW(static const xd3_smatcher __smatcher_slow;)
474IF_BUILD_FASTEST(static const xd3_smatcher __smatcher_fastest;)
475IF_BUILD_DEFAULT(static const xd3_smatcher __smatcher_default;)
476
477#if XD3_DEBUG
478#define SMALL_HASH_DEBUG1(s,inp) \
479 usize_t debug_hval = xd3_checksum_hash (& (s)->small_hash, \
480 xd3_scksum ((inp), (s)->smatcher.small_look))
481#define SMALL_HASH_DEBUG2(s,inp) \
482 XD3_ASSERT (debug_hval == xd3_checksum_hash (& (s)->small_hash, \
483 xd3_scksum ((inp), (s)->smatcher.small_look)))
484#else
485#define SMALL_HASH_DEBUG1(s,inp)
486#define SMALL_HASH_DEBUG2(s,inp)
487#endif /* XD3_DEBUG */
488
489/* Update the run-length state */
490#define NEXTRUN(c) do { if ((c) == run_c) { run_l += 1; } else { run_c = (c); run_l = 1; } } while (0)
491
492/* Update the checksum state. */
493#define LARGE_CKSUM_UPDATE(cksum,base,look) \
494 do { \
495 uint32_t old_c = PERMUTE((base)[0]); \
496 uint32_t new_c = PERMUTE((base)[(look)]); \
497 uint32_t low = (((cksum) & 0xffff) - old_c + new_c) & 0xffff; \
498 uint32_t high = (((cksum) >> 16) - (old_c * (look)) + low) & 0xffff; \
499 (cksum) = (high << 16) | low; \
500 } while (0)
501
502/* Multiply and add hash function */
503#if ARITH_SMALL_CKSUM
504#define SMALL_CKSUM_UPDATE(cksum,base,look) (cksum) = ((*(unsigned long*)(base+1)) * 71143)
505#else
506#define SMALL_CKSUM_UPDATE LARGE_CKSUM_UPDATE
507#endif
508
509/* Consume N bytes of input, only used by the decoder. */
510#define DECODE_INPUT(n) \
511 do { \
512 stream->total_in += (xoff_t) (n); \
513 stream->avail_in -= (n); \
514 stream->next_in += (n); \
515 } while (0)
516
517/* This CPP-conditional stuff can be cleaned up... */
518#if XD3_DEBUG
519#define IF_DEBUG(x) x
520#define DEBUG_ARG(x) , x
521#else
522#define IF_DEBUG(x)
523#define DEBUG_ARG(x)
524#endif
525#if XD3_DEBUG > 1
526#define IF_DEBUG1(x) x
527#else
528#define IF_DEBUG1(x)
529#endif
530#if XD3_DEBUG > 2
531#define IF_DEBUG2(x) x
532#else
533#define IF_DEBUG2(x)
534#endif
535#if REGRESSION_TEST
536#define IF_REGRESSION(x) x
537#else
538#define IF_REGRESSION(x)
539#endif
540
541/******************************************************************************************/
542
543#if XD3_ENCODER
544static void* xd3_alloc0 (xd3_stream *stream,
545 usize_t elts,
546 usize_t size);
547
548
549static xd3_output* xd3_alloc_output (xd3_stream *stream,
550 xd3_output *old_output);
551
552static int xd3_alloc_iopt (xd3_stream *stream, int elts);
553
554static void xd3_free_output (xd3_stream *stream,
555 xd3_output *output);
556
557static int xd3_emit_byte (xd3_stream *stream,
558 xd3_output **outputp,
559 uint8_t code);
560
561static int xd3_emit_bytes (xd3_stream *stream,
562 xd3_output **outputp,
563 const uint8_t *base,
564 usize_t size);
565
566static int xd3_emit_double (xd3_stream *stream, xd3_rinst *first, xd3_rinst *second, uint code);
567static int xd3_emit_single (xd3_stream *stream, xd3_rinst *single, uint code);
568
569static usize_t xd3_sizeof_output (xd3_output *output);
570
571static int xd3_source_match_setup (xd3_stream *stream, xoff_t srcpos);
572static int xd3_source_extend_match (xd3_stream *stream);
573static int xd3_srcwin_setup (xd3_stream *stream);
574static usize_t xd3_iopt_last_matched (xd3_stream *stream);
575static int xd3_emit_uint32_t (xd3_stream *stream, xd3_output **output, uint32_t num);
576
577#endif /* XD3_ENCODER */
578
579static int xd3_decode_allocate (xd3_stream *stream, usize_t size,
580 uint8_t **copied1, usize_t *alloc1,
581 uint8_t **copied2, usize_t *alloc2);
582
583static void xd3_compute_code_table_string (const xd3_dinst *code_table, uint8_t *str);
584static void* xd3_alloc (xd3_stream *stream, usize_t elts, usize_t size);
585static void xd3_free (xd3_stream *stream, void *ptr);
586
587static int xd3_read_uint32_t (xd3_stream *stream, const uint8_t **inpp,
588 const uint8_t *max, uint32_t *valp);
589
590#if REGRESSION_TEST
591static int xd3_selftest (void);
592#endif
593
594/******************************************************************************************/
595
596#define UINT32_OFLOW_MASK 0xfe000000U
597#define UINT64_OFLOW_MASK 0xfe00000000000000ULL
598
599#ifndef UINT32_MAX
600#define UINT32_MAX 4294967295U
601#endif
602
603#ifndef UINT64_MAX
604#define UINT64_MAX 18446744073709551615ULL
605#endif
606
607#if SIZEOF_USIZE_T == 4
608#define USIZE_T_MAX UINT32_MAX
609#define xd3_decode_size xd3_decode_uint32_t
610#define xd3_emit_size xd3_emit_uint32_t
611#define xd3_sizeof_size xd3_sizeof_uint32_t
612#define xd3_read_size xd3_read_uint32_t
613#elif SIZEOF_USIZE_T == 8
614#define USIZE_T_MAX UINT64_MAX
615#define xd3_decode_size xd3_decode_uint64_t
616#define xd3_emit_size xd3_emit_uint64_t
617#define xd3_sizeof_size xd3_sizeof_uint64_t
618#define xd3_read_size xd3_read_uint64_t
619#endif
620
621#if SIZEOF_XOFF_T == 4
622#define XOFF_T_MAX UINT32_MAX
623#define xd3_decode_offset xd3_decode_uint32_t
624#define xd3_emit_offset xd3_emit_uint32_t
625#elif SIZEOF_XOFF_T == 8
626#define XOFF_T_MAX UINT64_MAX
627#define xd3_decode_offset xd3_decode_uint64_t
628#define xd3_emit_offset xd3_emit_uint64_t
629#endif
630
631#define USIZE_T_OVERFLOW(a,b) ((USIZE_T_MAX - (usize_t) (a)) < (usize_t) (b))
632#define XOFF_T_OVERFLOW(a,b) ((XOFF_T_MAX - (xoff_t) (a)) < (xoff_t) (b))
633
634const char* xd3_strerror (int ret)
635{
636 switch (ret)
637 {
638 case XD3_INPUT: return "XD3_INPUT";
639 case XD3_OUTPUT: return "XD3_OUTPUT";
640 case XD3_GETSRCBLK: return "XD3_GETSRCBLK";
641 case XD3_GOTHEADER: return "XD3_GOTHEADER";
642 case XD3_WINSTART: return "XD3_WINSTART";
643 case XD3_WINFINISH: return "XD3_WINFINISH";
644 case XD3_TOOFARBACK: return "XD3_TOOFARBACK";
645 case XD3_INTERNAL: return "XD3_INTERNAL";
646 }
647 return NULL;
648}
649
650/******************************************************************************************/
651
652#if SECONDARY_ANY == 0
653#define IF_SEC(x)
654#define IF_NSEC(x) x
655#else /* yuck */
656#define IF_SEC(x) x
657#define IF_NSEC(x)
658#include "xdelta3-second.h"
659#endif /* SECONDARY_ANY */
660
661#if SECONDARY_FGK
662#include "xdelta3-fgk.h"
663
664static const xd3_sec_type fgk_sec_type =
665{
666 VCD_FGK_ID,
667 "FGK Adaptive Huffman",
668 SEC_NOFLAGS,
669 (xd3_sec_stream* (*)()) fgk_alloc,
670 (void (*)()) fgk_destroy,
671 (void (*)()) fgk_init,
672 (int (*)()) xd3_decode_fgk,
673 IF_ENCODER((int (*)()) xd3_encode_fgk)
674};
675
676#define IF_FGK(x) x
677#define FGK_CASE(s) \
678 s->sec_type = & fgk_sec_type; \
679 break;
680#else
681#define IF_FGK(x)
682#define FGK_CASE(s) \
683 s->msg = "unavailable secondary compressor: FGK Adaptive Huffman"; \
684 return XD3_INTERNAL;
685#endif
686
687#if SECONDARY_DJW
688#include "xdelta3-djw.h"
689
690static const xd3_sec_type djw_sec_type =
691{
692 VCD_DJW_ID,
693 "Static Huffman",
694 SEC_COUNT_FREQS,
695 (xd3_sec_stream* (*)()) djw_alloc,
696 (void (*)()) djw_destroy,
697 (void (*)()) djw_init,
698 (int (*)()) xd3_decode_huff,
699 IF_ENCODER((int (*)()) xd3_encode_huff)
700};
701
702#define IF_DJW(x) x
703#define DJW_CASE(s) \
704 s->sec_type = & djw_sec_type; \
705 break;
706#else
707#define IF_DJW(x)
708#define DJW_CASE(s) \
709 s->msg = "unavailable secondary compressor: DJW Static Huffman"; \
710 return XD3_INTERNAL;
711#endif
712
713/******************************************************************************************/
714
715/* Process the inline pass. */
716#define __XDELTA3_C_INLINE_PASS__
717#include "xdelta3.c"
718#undef __XDELTA3_C_INLINE_PASS__
719
720/* Process template passes - this includes xdelta3.c several times. */
721#define __XDELTA3_C_TEMPLATE_PASS__
722#include "xdelta3-cfgs.h"
723#undef __XDELTA3_C_TEMPLATE_PASS__
724
725#if XD3_MAIN || PYTHON_MODULE || SWIG_MODULE
726#include "xdelta3-main.h"
727#endif
728
729#if REGRESSION_TEST
730#include "xdelta3-test.h"
731#endif
732
733#if PYTHON_MODULE
734#include "xdelta3-python.h"
735#endif
736
737#endif /* __XDELTA3_C_HEADER_PASS__ */
738#ifdef __XDELTA3_C_INLINE_PASS__
739
740/******************************************************************************************
741 Instruction tables
742 ******************************************************************************************/
743
744/* The following code implements a parametrized description of the
745 * code table given above for a few reasons. It is not necessary for
746 * implementing the standard, to support compression with variable
747 * tables, so an implementation is only required to know the default
748 * code table to begin decompression. (If the encoder uses an
749 * alternate table, the table is included in compressed form inside
750 * the VCDIFF file.)
751 *
752 * Before adding variable-table support there were two functions which
753 * were hard-coded to the default table above.
754 * xd3_compute_default_table() would create the default table by
755 * filling a 256-elt array of xd3_dinst values. The corresponding
756 * function, xd3_choose_instruction(), would choose an instruction
757 * based on the hard-coded parameters of the default code table.
758 *
759 * Notes: The parametrized code table description here only generates
760 * tables of a certain regularity similar to the default table by
761 * allowing to vary the distribution of single- and
762 * double-instructions and change the number of near and same copy
763 * modes. More exotic tables are only possible by extending this
764 * code.
765 *
766 * For performance reasons, both the parametrized and non-parametrized
767 * versions of xd3_choose_instruction remain. The parametrized
768 * version is only needed for testing multi-table decoding support.
769 * If ever multi-table encoding is required, this can be optimized by
770 * compiling static functions for each table.
771 */
772
773/* The XD3_CHOOSE_INSTRUCTION calls xd3_choose_instruction with the
774 * table description when GENERIC_ENCODE_TABLES are in use. The
775 * IF_GENCODETBL macro enables generic-code-table specific code. */
776#if GENERIC_ENCODE_TABLES
777#define XD3_CHOOSE_INSTRUCTION(stream,prev,inst) xd3_choose_instruction (stream->code_table_desc, prev, inst)
778#define IF_GENCODETBL(x) x
779#else
780#define XD3_CHOOSE_INSTRUCTION(stream,prev,inst) xd3_choose_instruction (prev, inst)
781#define IF_GENCODETBL(x)
782#endif
783
784/* This structure maintains information needed by
785 * xd3_choose_instruction to compute the code for a double instruction
786 * by first indexing an array of code_table_sizes by copy mode, then
787 * using (offset + (muliplier * X)) */
788struct _xd3_code_table_sizes {
789 uint8_t cpy_max;
790 uint8_t offset;
791 uint8_t mult;
792};
793
794/* This contains a complete description of a code table. */
795struct _xd3_code_table_desc
796{
797 /* Assumes a single RUN instruction */
798 /* Assumes that MIN_MATCH is 4 */
799
800 uint8_t add_sizes; /* Number of immediate-size single adds (default 17) */
801 uint8_t near_modes; /* Number of near copy modes (default 4) */
802 uint8_t same_modes; /* Number of same copy modes (default 3) */
803 uint8_t cpy_sizes; /* Number of immediate-size single copies (default 15) */
804
805 uint8_t addcopy_add_max; /* Maximum add size for an add-copy double instruction, all modes (default 4) */
806 uint8_t addcopy_near_cpy_max; /* Maximum cpy size for an add-copy double instruction, up through VCD_NEAR modes (default 6) */
807 uint8_t addcopy_same_cpy_max; /* Maximum cpy size for an add-copy double instruction, VCD_SAME modes (default 4) */
808
809 uint8_t copyadd_add_max; /* Maximum add size for a copy-add double instruction, all modes (default 1) */
810 uint8_t copyadd_near_cpy_max; /* Maximum cpy size for a copy-add double instruction, up through VCD_NEAR modes (default 4) */
811 uint8_t copyadd_same_cpy_max; /* Maximum cpy size for a copy-add double instruction, VCD_SAME modes (default 4) */
812
813 xd3_code_table_sizes addcopy_max_sizes[MAX_MODES];
814 xd3_code_table_sizes copyadd_max_sizes[MAX_MODES];
815};
816
817/* The rfc3284 code table is represented: */
818static const xd3_code_table_desc __rfc3284_code_table_desc = {
819 17, /* add sizes */
820 4, /* near modes */
821 3, /* same modes */
822 15, /* copy sizes */
823
824 4, /* add-copy max add */
825 6, /* add-copy max cpy, near */
826 4, /* add-copy max cpy, same */
827
828 1, /* copy-add max add */
829 4, /* copy-add max cpy, near */
830 4, /* copy-add max cpy, same */
831
832 /* addcopy */
833 { {6,163,3},{6,175,3},{6,187,3},{6,199,3},{6,211,3},{6,223,3},{4,235,1},{4,239,1},{4,243,1} },
834 /* copyadd */
835 { {4,247,1},{4,248,1},{4,249,1},{4,250,1},{4,251,1},{4,252,1},{4,253,1},{4,254,1},{4,255,1} },
836};
837
838#if GENERIC_ENCODE_TABLES
839/* An alternate code table for testing (5 near, 0 same):
840 *
841 * TYPE SIZE MODE TYPE SIZE MODE INDEX
842 * ---------------------------------------------------------------
843 * 1. Run 0 0 Noop 0 0 0
844 * 2. Add 0, [1,23] 0 Noop 0 0 [1,24]
845 * 3. Copy 0, [4,20] 0 Noop 0 0 [25,42]
846 * 4. Copy 0, [4,20] 1 Noop 0 0 [43,60]
847 * 5. Copy 0, [4,20] 2 Noop 0 0 [61,78]
848 * 6. Copy 0, [4,20] 3 Noop 0 0 [79,96]
849 * 7. Copy 0, [4,20] 4 Noop 0 0 [97,114]
850 * 8. Copy 0, [4,20] 5 Noop 0 0 [115,132]
851 * 9. Copy 0, [4,20] 6 Noop 0 0 [133,150]
852 * 10. Add [1,4] 0 Copy [4,6] 0 [151,162]
853 * 11. Add [1,4] 0 Copy [4,6] 1 [163,174]
854 * 12. Add [1,4] 0 Copy [4,6] 2 [175,186]
855 * 13. Add [1,4] 0 Copy [4,6] 3 [187,198]
856 * 14. Add [1,4] 0 Copy [4,6] 4 [199,210]
857 * 15. Add [1,4] 0 Copy [4,6] 5 [211,222]
858 * 16. Add [1,4] 0 Copy [4,6] 6 [223,234]
859 * 17. Copy 4 [0,6] Add [1,3] 0 [235,255]
860 * --------------------------------------------------------------- */
861static const xd3_code_table_desc __alternate_code_table_desc = {
862 23, /* add sizes */
863 5, /* near modes */
864 0, /* same modes */
865 17, /* copy sizes */
866
867 4, /* add-copy max add */
868 6, /* add-copy max cpy, near */
869 0, /* add-copy max cpy, same */
870
871 3, /* copy-add max add */
872 4, /* copy-add max cpy, near */
873 0, /* copy-add max cpy, same */
874
875 /* addcopy */
876 { {6,151,3},{6,163,3},{6,175,3},{6,187,3},{6,199,3},{6,211,3},{6,223,3},{0,0,0},{0,0,0} },
877 /* copyadd */
878 { {4,235,1},{4,238,1},{4,241,1},{4,244,1},{4,247,1},{4,250,1},{4,253,1},{0,0,0},{0,0,0} },
879};
880#endif
881
882/* Computes code table entries of TBL using the specified description. */
883static void
884xd3_build_code_table (const xd3_code_table_desc *desc, xd3_dinst *tbl)
885{
886 int size1, size2, mode;
887 int cpy_modes = 2 + desc->near_modes + desc->same_modes;
888 xd3_dinst *d = tbl;
889
890 (d++)->type1 = XD3_RUN;
891 (d++)->type1 = XD3_ADD;
892
893 for (size1 = 1; size1 <= desc->add_sizes; size1 += 1, d += 1)
894 {
895 d->type1 = XD3_ADD;
896 d->size1 = size1;
897 }
898
899 for (mode = 0; mode < cpy_modes; mode += 1)
900 {
901 (d++)->type1 = XD3_CPY + mode;
902
903 for (size1 = MIN_MATCH; size1 < MIN_MATCH + desc->cpy_sizes; size1 += 1, d += 1)
904 {
905 d->type1 = XD3_CPY + mode;
906 d->size1 = size1;
907 }
908 }
909
910 for (mode = 0; mode < cpy_modes; mode += 1)
911 {
912 for (size1 = 1; size1 <= desc->addcopy_add_max; size1 += 1)
913 {
914 int max = (mode < 2 + desc->near_modes) ? desc->addcopy_near_cpy_max : desc->addcopy_same_cpy_max;
915
916 for (size2 = MIN_MATCH; size2 <= max; size2 += 1, d += 1)
917 {
918 d->type1 = XD3_ADD;
919 d->size1 = size1;
920 d->type2 = XD3_CPY + mode;
921 d->size2 = size2;
922 }
923 }
924 }
925
926 for (mode = 0; mode < cpy_modes; mode += 1)
927 {
928 int max = (mode < 2 + desc->near_modes) ? desc->copyadd_near_cpy_max : desc->copyadd_same_cpy_max;
929
930 for (size1 = MIN_MATCH; size1 <= max; size1 += 1)
931 {
932 for (size2 = 1; size2 <= desc->copyadd_add_max; size2 += 1, d += 1)
933 {
934 d->type1 = XD3_CPY + mode;
935 d->size1 = size1;
936 d->type2 = XD3_ADD;
937 d->size2 = size2;
938 }
939 }
940 }
941
942 XD3_ASSERT (d - tbl == 256);
943}
944
945/* This function generates the static default code table. */
946static const xd3_dinst*
947xd3_rfc3284_code_table (void)
948{
949 static xd3_dinst __rfc3284_code_table[256];
950
951 if (__rfc3284_code_table[0].type1 != XD3_RUN)
952 {
953 xd3_build_code_table (& __rfc3284_code_table_desc, __rfc3284_code_table);
954 }
955
956 return __rfc3284_code_table;
957}
958
959#if XD3_ENCODER
960#if GENERIC_ENCODE_TABLES
961/* This function generates the alternate code table. */
962static const xd3_dinst*
963xd3_alternate_code_table (void)
964{
965 static xd3_dinst __alternate_code_table[256];
966
967 if (__alternate_code_table[0].type1 != XD3_RUN)
968 {
969 xd3_build_code_table (& __alternate_code_table_desc, __alternate_code_table);
970 }
971
972 return __alternate_code_table;
973}
974
975/* This function computes the ideal second instruction INST based on preceding instruction
976 * PREV. If it is possible to issue a double instruction based on this pair it sets
977 * PREV->code2, otherwise it sets INST->code1. */
978static void
979xd3_choose_instruction (const xd3_code_table_desc *desc, xd3_rinst *prev, xd3_rinst *inst)
980{
981 switch (inst->type)
982 {
983 case XD3_RUN:
984 /* The 0th instruction is RUN */
985 inst->code1 = 0;
986 break;
987
988 case XD3_ADD:
989
990 if (inst->size > desc->add_sizes)
991 {
992 /* The first instruction is non-immediate ADD */
993 inst->code1 = 1;
994 }
995 else
996 {
997 /* The following ADD_SIZES instructions are immediate ADDs */
998 inst->code1 = 1 + inst->size;
999
1000 /* Now check for a possible COPY-ADD double instruction */
1001 if (prev != NULL)
1002 {
1003 int prev_mode = prev->type - XD3_CPY;
1004
1005 /* If previous is a copy. Note: as long as the previous is not a RUN
1006 * instruction, it should be a copy because it cannot be an add. This check
1007 * is more clear. */
1008 if (prev_mode >= 0 && inst->size <= desc->copyadd_add_max)
1009 {
1010 const xd3_code_table_sizes *sizes = & desc->copyadd_max_sizes[prev_mode];
1011
1012 /* This check and the inst->size-<= above are == in the default table. */
1013 if (prev->size <= sizes->cpy_max)
1014 {
1015 /* The second and third exprs are 0 in the default table. */
1016 prev->code2 = sizes->offset + (sizes->mult * (prev->size - MIN_MATCH)) + (inst->size - MIN_ADD);
1017 }
1018 }
1019 }
1020 }
1021 break;
1022
1023 default:
1024 {
1025 int mode = inst->type - XD3_CPY;
1026
1027 /* The large copy instruction is offset by the run, large add, and immediate adds,
1028 * then multipled by the number of immediate copies plus one (the large copy)
1029 * (i.e., if there are 15 immediate copy instructions then there are 16 copy
1030 * instructions per mode). */
1031 inst->code1 = 2 + desc->add_sizes + (1 + desc->cpy_sizes) * mode;
1032
1033 /* Now if the copy is short enough for an immediate instruction. */
1034 if (inst->size < MIN_MATCH + desc->cpy_sizes)
1035 {
1036 inst->code1 += inst->size + 1 - MIN_MATCH;
1037
1038 /* Now check for a possible ADD-COPY double instruction. */
1039 if ( (prev != NULL) &&
1040 (prev->type == XD3_ADD) &&
1041 (prev->size <= desc->addcopy_add_max) )
1042 {
1043 const xd3_code_table_sizes *sizes = & desc->addcopy_max_sizes[mode];
1044
1045 if (inst->size <= sizes->cpy_max)
1046 {
1047 prev->code2 = sizes->offset + (sizes->mult * (prev->size - MIN_ADD)) + (inst->size - MIN_MATCH);
1048 }
1049 }
1050 }
1051 }
1052 }
1053}
1054#else /* GENERIC_ENCODE_TABLES */
1055
1056/* This version of xd3_choose_instruction is hard-coded for the default table. */
1057static void
1058xd3_choose_instruction (/* const xd3_code_table_desc *desc,*/ xd3_rinst *prev, xd3_rinst *inst)
1059{
1060 switch (inst->type)
1061 {
1062 case XD3_RUN:
1063 inst->code1 = 0;
1064 break;
1065
1066 case XD3_ADD:
1067 inst->code1 = 1;
1068
1069 if (inst->size <= 17)
1070 {
1071 inst->code1 += inst->size;
1072
1073 if ( (inst->size == 1) &&
1074 (prev != NULL) &&
1075 (prev->size == 4) &&
1076 (prev->type >= XD3_CPY) )
1077 {
1078 prev->code2 = 247 + (prev->type - XD3_CPY);
1079 }
1080 }
1081
1082 break;
1083
1084 default:
1085 {
1086 int mode = inst->type - XD3_CPY;
1087
1088 XD3_ASSERT (inst->type >= XD3_CPY && inst->type < 12);
1089
1090 inst->code1 = 19 + 16 * mode;
1091
1092 if (inst->size <= 18)
1093 {
1094 inst->code1 += inst->size - 3;
1095
1096 if ( (prev != NULL) &&
1097 (prev->type == XD3_ADD) &&
1098 (prev->size <= 4) )
1099 {
1100 if ( (inst->size <= 6) &&
1101 (mode <= 5) )
1102 {
1103 prev->code2 = 163 + (mode * 12) + (3 * (prev->size - 1)) + (inst->size - 4);
1104
1105 XD3_ASSERT (prev->code2 <= 234);
1106 }
1107 else if ( (inst->size == 4) &&
1108 (mode >= 6) )
1109 {
1110 prev->code2 = 235 + ((mode - 6) * 4) + (prev->size - 1);
1111
1112 XD3_ASSERT (prev->code2 <= 246);
1113 }
1114 }
1115 }
1116
1117 XD3_ASSERT (inst->code1 <= 162);
1118 }
1119 break;
1120 }
1121}
1122#endif /* GENERIC_ENCODE_TABLES */
1123
1124/******************************************************************************************
1125 Instruction table encoder/decoder
1126 ******************************************************************************************/
1127
1128#if GENERIC_ENCODE_TABLES
1129#if GENERIC_ENCODE_TABLES_COMPUTE == 0
1130
1131/* In this case, we hard-code the result of compute_code_table_encoding for each alternate
1132 * code table, presuming that saves time/space. This has been 131 bytes, but secondary
1133 * compression was turned off. */
1134static const uint8_t __alternate_code_table_compressed[178] =
1135{0xd6,0xc3,0xc4,0x00,0x00,0x01,0x8a,0x6f,0x40,0x81,0x27,0x8c,0x00,0x00,0x4a,0x4a,0x0d,0x02,0x01,0x03,
11360x01,0x03,0x00,0x01,0x00,0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x07,0x08,0x09,0x0a,0x0b,0x0c,0x0d,0x0e,
11370x0f,0x10,0x11,0x12,0x13,0x14,0x15,0x16,0x17,0x00,0x01,0x01,0x01,0x02,0x02,0x02,0x03,0x03,0x03,0x04,
11380x04,0x04,0x04,0x00,0x04,0x05,0x06,0x01,0x02,0x03,0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x05,0x05,0x05,
11390x06,0x06,0x06,0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x00,0x02,0x00,0x18,0x13,0x63,0x00,0x1b,0x00,0x54,
11400x00,0x15,0x23,0x6f,0x00,0x28,0x13,0x54,0x00,0x15,0x01,0x1a,0x31,0x23,0x6c,0x0d,0x23,0x48,0x00,0x15,
11410x93,0x6f,0x00,0x28,0x04,0x23,0x51,0x04,0x32,0x00,0x2b,0x00,0x12,0x00,0x12,0x00,0x12,0x00,0x12,0x00,
11420x12,0x00,0x12,0x53,0x57,0x9c,0x07,0x43,0x6f,0x00,0x34,0x00,0x0c,0x00,0x0c,0x00,0x0c,0x00,0x0c,0x00,
11430x0c,0x00,0x0c,0x00,0x15,0x00,0x82,0x6f,0x00,0x15,0x12,0x0c,0x00,0x03,0x03,0x00,0x06,0x00,};
1144
1145static int
1146xd3_compute_alternate_table_encoding (xd3_stream *stream, const uint8_t **data, usize_t *size)
1147{
1148 (*data) = __alternate_code_table_compressed;
1149 (*size) = sizeof (__alternate_code_table_compressed);
1150 return 0;
1151}
1152
1153#else
1154
1155/* The alternate code table will be computed and stored here. */
1156static uint8_t __alternate_code_table_compressed[CODE_TABLE_VCDIFF_SIZE];
1157static usize_t __alternate_code_table_compressed_size;
1158
1159/* This function generates a delta describing the code table for encoding within a VCDIFF
1160 * file. This function is NOT thread safe because it is only intended that this function
1161 * is used to generate statically-compiled strings. */
1162int xd3_compute_code_table_encoding (xd3_stream *in_stream, const xd3_dinst *code_table,
1163 uint8_t *comp_string, usize_t *comp_string_size)
1164{
1165 /* TODO: use xd3_encode_memory() */
1166 uint8_t dflt_string[CODE_TABLE_STRING_SIZE];
1167 uint8_t code_string[CODE_TABLE_STRING_SIZE];
1168 xd3_stream stream;
1169 xd3_source source;
1170 xd3_config config;
1171 int ret;
1172
1173 memset (& source, 0, sizeof (source));
1174
1175 xd3_compute_code_table_string (xd3_rfc3284_code_table (), dflt_string);
1176 xd3_compute_code_table_string (code_table, code_string);
1177
1178 /* Use DJW secondary compression if it is on by default. This saves about 20 bytes. */
1179 xd3_init_config (& config, XD3_FLUSH | (SECONDARY_DJW ? XD3_SEC_DJW : 0));
1180
1181 /* Be exhaustive. */
1182 config.sprevsz = 1<<11;
1183 config.srcwin_maxsz = CODE_TABLE_STRING_SIZE;
1184
1185 config.smatch_cfg = XD3_SMATCH_SOFT;
1186 config.smatcher_soft.large_look = 4;
1187 config.smatcher_soft.large_step = 1;
1188 config.smatcher_soft.small_look = 4;
1189 config.smatcher_soft.small_chain = CODE_TABLE_STRING_SIZE;
1190 config.smatcher_soft.small_lchain = CODE_TABLE_STRING_SIZE;
1191 config.smatcher_soft.max_lazy = CODE_TABLE_STRING_SIZE;
1192 config.smatcher_soft.long_enough = CODE_TABLE_STRING_SIZE;
1193
1194 if ((ret = xd3_config_stream (& stream, & config))) { goto fail; }
1195
1196 source.size = CODE_TABLE_STRING_SIZE;
1197 source.blksize = CODE_TABLE_STRING_SIZE;
1198 source.onblk = CODE_TABLE_STRING_SIZE;
1199 source.name = "";
1200 source.curblk = dflt_string;
1201 source.curblkno = 0;
1202
1203 if ((ret = xd3_set_source (& stream, & source))) { goto fail; }
1204
1205 if ((ret = xd3_encode_stream (& stream, code_string, CODE_TABLE_STRING_SIZE,
1206 comp_string, comp_string_size, CODE_TABLE_VCDIFF_SIZE))) { goto fail; }
1207
1208 fail:
1209
1210 in_stream->msg = stream.msg;
1211 xd3_free_stream (& stream);
1212 return ret;
1213}
1214
1215/* Compute a delta between alternate and rfc3284 tables. As soon as another alternate
1216 * table is added, this code should become generic. For now there is only one alternate
1217 * table for testing. */
1218static int
1219xd3_compute_alternate_table_encoding (xd3_stream *stream, const uint8_t **data, usize_t *size)
1220{
1221 int ret;
1222
1223 if (__alternate_code_table_compressed[0] == 0)
1224 {
1225 if ((ret = xd3_compute_code_table_encoding (stream, xd3_alternate_code_table (),
1226 __alternate_code_table_compressed,
1227 & __alternate_code_table_compressed_size)))
1228 {
1229 return ret;
1230 }
1231
1232 /* During development of a new code table, enable this variable to print the new
1233 * static contents and determine its size. At run time the table will be filled in
1234 * appropriately, but at least it should have the proper size beforehand. */
1235#if GENERIC_ENCODE_TABLES_COMPUTE_PRINT
1236 {
1237 int i;
1238
1239 DP(RINT, "\nstatic const usize_t __alternate_code_table_compressed_size = %u;\n",
1240 __alternate_code_table_compressed_size);
1241
1242 DP(RINT, "static const uint8_t __alternate_code_table_compressed[%u] =\n{",
1243 __alternate_code_table_compressed_size);
1244
1245 for (i = 0; i < __alternate_code_table_compressed_size; i += 1)
1246 {
1247 DP(RINT, "0x%02x,", __alternate_code_table_compressed[i]);
1248 if ((i % 20) == 19) { DP(RINT, "\n"); }
1249 }
1250
1251 DP(RINT, "};\n");
1252 }
1253#endif
1254 }
1255
1256 (*data) = __alternate_code_table_compressed;
1257 (*size) = __alternate_code_table_compressed_size;
1258
1259 return 0;
1260}
1261#endif /* GENERIC_ENCODE_TABLES_COMPUTE != 0 */
1262#endif /* GENERIC_ENCODE_TABLES */
1263
1264#endif /* XD3_ENCODER */
1265
1266/* This function generates the 1536-byte string specified in sections 5.4 and 7 of
1267 * rfc3284, which is used to represent a code table within a VCDIFF file. */
1268void xd3_compute_code_table_string (const xd3_dinst *code_table, uint8_t *str)
1269{
1270 int i, s;
1271
1272 XD3_ASSERT (CODE_TABLE_STRING_SIZE == 6 * 256);
1273
1274 for (s = 0; s < 6; s += 1)
1275 {
1276 for (i = 0; i < 256; i += 1)
1277 {
1278 switch (s)
1279 {
1280 case 0: *str++ = (code_table[i].type1 >= XD3_CPY ? XD3_CPY : code_table[i].type1); break;
1281 case 1: *str++ = (code_table[i].type2 >= XD3_CPY ? XD3_CPY : code_table[i].type2); break;
1282 case 2: *str++ = (code_table[i].size1); break;
1283 case 3: *str++ = (code_table[i].size2); break;
1284 case 4: *str++ = (code_table[i].type1 >= XD3_CPY ? code_table[i].type1 - XD3_CPY : 0); break;
1285 case 5: *str++ = (code_table[i].type2 >= XD3_CPY ? code_table[i].type2 - XD3_CPY : 0); break;
1286 }
1287 }
1288 }
1289}
1290
1291/* This function translates the code table string into the internal representation. The
1292 * stream's near and same-modes should already be set. */
1293static int
1294xd3_apply_table_string (xd3_stream *stream, const uint8_t *code_string)
1295{
1296 int i, s;
1297 int modes = TOTAL_MODES (stream);
1298 xd3_dinst *code_table;
1299
1300 if ((code_table = stream->code_table_alloc = xd3_alloc (stream, sizeof (xd3_dinst), 256)) == NULL)
1301 {
1302 return ENOMEM;
1303 }
1304
1305 for (s = 0; s < 6; s += 1)
1306 {
1307 for (i = 0; i < 256; i += 1)
1308 {
1309 switch (s)
1310 {
1311 case 0:
1312 if (*code_string > XD3_CPY)
1313 {
1314 stream->msg = "invalid code-table opcode";
1315 return XD3_INTERNAL;
1316 }
1317 code_table[i].type1 = *code_string++;
1318 break;
1319 case 1:
1320 if (*code_string > XD3_CPY)
1321 {
1322 stream->msg = "invalid code-table opcode";
1323 return XD3_INTERNAL;
1324 }
1325 code_table[i].type2 = *code_string++;
1326 break;
1327 case 2:
1328 if (*code_string != 0 && code_table[i].type1 == XD3_NOOP)
1329 {
1330 stream->msg = "invalid code-table size";
1331 return XD3_INTERNAL;
1332 }
1333 code_table[i].size1 = *code_string++;
1334 break;
1335 case 3:
1336 if (*code_string != 0 && code_table[i].type2 == XD3_NOOP)
1337 {
1338 stream->msg = "invalid code-table size";
1339 return XD3_INTERNAL;
1340 }
1341 code_table[i].size2 = *code_string++;
1342 break;
1343 case 4:
1344 if (*code_string >= modes)
1345 {
1346 stream->msg = "invalid code-table mode";
1347 return XD3_INTERNAL;
1348 }
1349 if (*code_string != 0 && code_table[i].type1 != XD3_CPY)
1350 {
1351 stream->msg = "invalid code-table mode";
1352 return XD3_INTERNAL;
1353 }
1354 code_table[i].type1 += *code_string++;
1355 break;
1356 case 5:
1357 if (*code_string >= modes)
1358 {
1359 stream->msg = "invalid code-table mode";
1360 return XD3_INTERNAL;
1361 }
1362 if (*code_string != 0 && code_table[i].type2 != XD3_CPY)
1363 {
1364 stream->msg = "invalid code-table mode";
1365 return XD3_INTERNAL;
1366 }
1367 code_table[i].type2 += *code_string++;
1368 break;
1369 }
1370 }
1371 }
1372
1373 stream->code_table = code_table;
1374 return 0;
1375}
1376
1377/* This function applies a code table delta and returns an actual code table. */
1378static int
1379xd3_apply_table_encoding (xd3_stream *in_stream, const uint8_t *data, usize_t size)
1380{
1381 uint8_t dflt_string[CODE_TABLE_STRING_SIZE];
1382 uint8_t code_string[CODE_TABLE_STRING_SIZE];
1383 usize_t code_size;
1384 xd3_stream stream;
1385 xd3_source source;
1386 int ret;
1387
1388 /* The default code table string can be cached if alternate code tables ever become
1389 * popular. */
1390 xd3_compute_code_table_string (xd3_rfc3284_code_table (), dflt_string);
1391
1392 source.size = CODE_TABLE_STRING_SIZE;
1393 source.blksize = CODE_TABLE_STRING_SIZE;
1394 source.onblk = CODE_TABLE_STRING_SIZE;
1395 source.name = "rfc3284 code table";
1396 source.curblk = dflt_string;
1397 source.curblkno = 0;
1398
1399 if ((ret = xd3_config_stream (& stream, NULL)) ||
1400 (ret = xd3_set_source (& stream, & source)) ||
1401 (ret = xd3_decode_stream (& stream, data, size, code_string, & code_size, sizeof (code_string))))
1402 {
1403 in_stream->msg = stream.msg;
1404 goto fail;
1405 }
1406
1407 if (code_size != sizeof (code_string))
1408 {
1409 stream.msg = "corrupt code-table encoding";
1410 ret = XD3_INTERNAL;
1411 goto fail;
1412 }
1413
1414 if ((ret = xd3_apply_table_string (in_stream, code_string))) { goto fail; }
1415
1416 fail:
1417
1418 xd3_free_stream (& stream);
1419 return ret;
1420}
1421
1422/******************************************************************************************
1423 Permute stuff
1424 ******************************************************************************************/
1425
1426#if HASH_PERMUTE == 0
1427#define PERMUTE(x) (x)
1428#else
1429#define PERMUTE(x) (__single_hash[(uint)x])
1430
1431static const uint16_t __single_hash[256] =
1432{
1433 /* Random numbers generated using SLIB's pseudo-random number generator. This hashes
1434 * the input alphabet. */
1435 0xbcd1, 0xbb65, 0x42c2, 0xdffe, 0x9666, 0x431b, 0x8504, 0xeb46,
1436 0x6379, 0xd460, 0xcf14, 0x53cf, 0xdb51, 0xdb08, 0x12c8, 0xf602,
1437 0xe766, 0x2394, 0x250d, 0xdcbb, 0xa678, 0x02af, 0xa5c6, 0x7ea6,
1438 0xb645, 0xcb4d, 0xc44b, 0xe5dc, 0x9fe6, 0x5b5c, 0x35f5, 0x701a,
1439 0x220f, 0x6c38, 0x1a56, 0x4ca3, 0xffc6, 0xb152, 0x8d61, 0x7a58,
1440 0x9025, 0x8b3d, 0xbf0f, 0x95a3, 0xe5f4, 0xc127, 0x3bed, 0x320b,
1441 0xb7f3, 0x6054, 0x333c, 0xd383, 0x8154, 0x5242, 0x4e0d, 0x0a94,
1442 0x7028, 0x8689, 0x3a22, 0x0980, 0x1847, 0xb0f1, 0x9b5c, 0x4176,
1443 0xb858, 0xd542, 0x1f6c, 0x2497, 0x6a5a, 0x9fa9, 0x8c5a, 0x7743,
1444 0xa8a9, 0x9a02, 0x4918, 0x438c, 0xc388, 0x9e2b, 0x4cad, 0x01b6,
1445 0xab19, 0xf777, 0x365f, 0x1eb2, 0x091e, 0x7bf8, 0x7a8e, 0x5227,
1446 0xeab1, 0x2074, 0x4523, 0xe781, 0x01a3, 0x163d, 0x3b2e, 0x287d,
1447 0x5e7f, 0xa063, 0xb134, 0x8fae, 0x5e8e, 0xb7b7, 0x4548, 0x1f5a,
1448 0xfa56, 0x7a24, 0x900f, 0x42dc, 0xcc69, 0x02a0, 0x0b22, 0xdb31,
1449 0x71fe, 0x0c7d, 0x1732, 0x1159, 0xcb09, 0xe1d2, 0x1351, 0x52e9,
1450 0xf536, 0x5a4f, 0xc316, 0x6bf9, 0x8994, 0xb774, 0x5f3e, 0xf6d6,
1451 0x3a61, 0xf82c, 0xcc22, 0x9d06, 0x299c, 0x09e5, 0x1eec, 0x514f,
1452 0x8d53, 0xa650, 0x5c6e, 0xc577, 0x7958, 0x71ac, 0x8916, 0x9b4f,
1453 0x2c09, 0x5211, 0xf6d8, 0xcaaa, 0xf7ef, 0x287f, 0x7a94, 0xab49,
1454 0xfa2c, 0x7222, 0xe457, 0xd71a, 0x00c3, 0x1a76, 0xe98c, 0xc037,
1455 0x8208, 0x5c2d, 0xdfda, 0xe5f5, 0x0b45, 0x15ce, 0x8a7e, 0xfcad,
1456 0xaa2d, 0x4b5c, 0xd42e, 0xb251, 0x907e, 0x9a47, 0xc9a6, 0xd93f,
1457 0x085e, 0x35ce, 0xa153, 0x7e7b, 0x9f0b, 0x25aa, 0x5d9f, 0xc04d,
1458 0x8a0e, 0x2875, 0x4a1c, 0x295f, 0x1393, 0xf760, 0x9178, 0x0f5b,
1459 0xfa7d, 0x83b4, 0x2082, 0x721d, 0x6462, 0x0368, 0x67e2, 0x8624,
1460 0x194d, 0x22f6, 0x78fb, 0x6791, 0xb238, 0xb332, 0x7276, 0xf272,
1461 0x47ec, 0x4504, 0xa961, 0x9fc8, 0x3fdc, 0xb413, 0x007a, 0x0806,
1462 0x7458, 0x95c6, 0xccaa, 0x18d6, 0xe2ae, 0x1b06, 0xf3f6, 0x5050,
1463 0xc8e8, 0xf4ac, 0xc04c, 0xf41c, 0x992f, 0xae44, 0x5f1b, 0x1113,
1464 0x1738, 0xd9a8, 0x19ea, 0x2d33, 0x9698, 0x2fe9, 0x323f, 0xcde2,
1465 0x6d71, 0xe37d, 0xb697, 0x2c4f, 0x4373, 0x9102, 0x075d, 0x8e25,
1466 0x1672, 0xec28, 0x6acb, 0x86cc, 0x186e, 0x9414, 0xd674, 0xd1a5
1467};
1468#endif
1469
1470/******************************************************************************************
1471 Ctable stuff
1472 ******************************************************************************************/
1473
1474#if HASH_PRIME
1475static const usize_t __primes[] =
1476{
1477 11, 19, 37, 73, 109,
1478 163, 251, 367, 557, 823,
1479 1237, 1861, 2777, 4177, 6247,
1480 9371, 14057, 21089, 31627, 47431,
1481 71143, 106721, 160073, 240101, 360163,
1482 540217, 810343, 1215497, 1823231, 2734867,
1483 4102283, 6153409, 9230113, 13845163, 20767711,
1484 31151543, 46727321, 70090921, 105136301, 157704401,
1485 236556601, 354834919, 532252367, 798378509, 1197567719,
1486 1796351503
1487};
1488
1489static const usize_t __nprimes = SIZEOF_ARRAY (__primes);
1490#endif
1491
1492static INLINE uint32_t
1493xd3_checksum_hash (const xd3_hash_cfg *cfg, const uint32_t cksum)
1494{
1495#if HASH_PRIME
1496 /* If the table is prime compute the modulus. */
1497 return (cksum % cfg->size);
1498#else
1499 /* If the table is power-of-two compute the mask.*/
1500 return (cksum ^ (cksum >> cfg->shift)) & cfg->mask;
1501#endif
1502}
1503
1504/******************************************************************************************
1505 Create the hash table.
1506 ******************************************************************************************/
1507
1508static INLINE void
1509xd3_swap_uint8p (uint8_t** p1, uint8_t** p2)
1510{
1511 uint8_t *t = (*p1);
1512 (*p1) = (*p2);
1513 (*p2) = t;
1514}
1515
1516static INLINE void
1517xd3_swap_usize_t (usize_t* p1, usize_t* p2)
1518{
1519 usize_t t = (*p1);
1520 (*p1) = (*p2);
1521 (*p2) = t;
1522}
1523
1524/* It's not constant time, but it computes the log. */
1525static int
1526xd3_check_pow2 (usize_t value, usize_t *logof)
1527{
1528 usize_t x = 1;
1529 usize_t nolog;
1530 if (logof == NULL) {
1531 logof = &nolog;
1532 }
1533
1534 *logof = 0;
1535
1536 for (; x != 0; x <<= 1, *logof += 1)
1537 {
1538 if (x == value)
1539 {
1540 return 0;
1541 }
1542 }
1543
1544 return XD3_INTERNAL;
1545}
1546
1547static usize_t
1548xd3_round_blksize (usize_t sz, usize_t blksz)
1549{
1550 usize_t mod = sz & (blksz-1);
1551
1552 XD3_ASSERT (xd3_check_pow2 (blksz, NULL) == 0);
1553
1554 return mod ? (sz + (blksz - mod)) : sz;
1555}
1556
1557#if XD3_ENCODER
1558#if !HASH_PRIME
1559static usize_t
1560xd3_size_log2 (usize_t slots)
1561{
1562 int bits = 28; /* This should not be an unreasonable limit. */
1563 int i;
1564
1565 for (i = 3; i <= bits; i += 1)
1566 {
1567 if (slots < (1 << i))
1568 {
1569 bits = i-1;
1570 break;
1571 }
1572 }
1573
1574 return bits;
1575}
1576#endif
1577
1578static void
1579xd3_size_hashtable (xd3_stream *stream,
1580 usize_t slots,
1581 xd3_hash_cfg *cfg)
1582{
1583 /* initialize ctable: the number of hash buckets is computed from the table of primes or
1584 * the nearest power-of-two, in both cases rounding down in favor of using less
1585 * memory. */
1586
1587#if HASH_PRIME
1588 usize_t i;
1589
1590 cfg->size = __primes[__nprimes-1];
1591
1592 for (i = 1; i < __nprimes; i += 1)
1593 {
1594 if (slots < __primes[i])
1595 {
1596 cfg->size = __primes[i-1];
1597 break;
1598 }
1599 }
1600#else
1601 int bits = xd3_size_log2 (slots);
1602
1603 cfg->size = (1 << bits);
1604 cfg->mask = (cfg->size - 1);
1605 cfg->shift = min (32 - bits, 16);
1606#endif
1607}
1608#endif
1609
1610/******************************************************************************************
1611 Cksum function
1612 ******************************************************************************************/
1613
1614/* OPT: It turns out that the compiler can't unroll the loop as well as you can by hand. */
1615static INLINE uint32_t
1616xd3_lcksum (const uint8_t *seg, const int ln)
1617{
1618 int i = 0;
1619 uint32_t low = 0;
1620 uint32_t high = 0;
1621
1622 for (; i < ln; i += 1)
1623 {
1624 low += PERMUTE(*seg++);
1625 high += low;
1626 }
1627
1628 return ((high & 0xffff) << 16) | (low & 0xffff);
1629}
1630
1631#if ARITH_SMALL_CKSUM
1632static INLINE usize_t
1633xd3_scksum (const uint8_t *seg, const int ln)
1634{
1635 usize_t c;
1636 /* The -1 is because UPDATE operates on seg[1..ln] */
1637 SMALL_CKSUM_UPDATE (c,(seg-1),ln);
1638 return c;
1639}
1640#else
1641#define xd3_scksum(seg,ln) xd3_lcksum(seg,ln)
1642#endif
1643
1644/******************************************************************************************
1645 Adler32 stream function: code copied from Zlib, defined in RFC1950
1646 ******************************************************************************************/
1647
1648#define A32_BASE 65521L /* Largest prime smaller than 2^16 */
1649#define A32_NMAX 5552 /* NMAX is the largest n such that 255n(n+1)/2 + (n+1)(BASE-1) <= 2^32-1 */
1650
1651#define A32_DO1(buf,i) {s1 += buf[i]; s2 += s1;}
1652#define A32_DO2(buf,i) A32_DO1(buf,i); A32_DO1(buf,i+1);
1653#define A32_DO4(buf,i) A32_DO2(buf,i); A32_DO2(buf,i+2);
1654#define A32_DO8(buf,i) A32_DO4(buf,i); A32_DO4(buf,i+4);
1655#define A32_DO16(buf) A32_DO8(buf,0); A32_DO8(buf,8);
1656
1657static unsigned long adler32 (unsigned long adler, const uint8_t *buf, usize_t len)
1658{
1659 unsigned long s1 = adler & 0xffff;
1660 unsigned long s2 = (adler >> 16) & 0xffff;
1661 int k;
1662
1663 while (len > 0)
1664 {
1665 k = (len < A32_NMAX) ? len : A32_NMAX;
1666 len -= k;
1667
1668 while (k >= 16)
1669 {
1670 A32_DO16(buf);
1671 buf += 16;
1672 k -= 16;
1673 }
1674
1675 if (k != 0)
1676 {
1677 do
1678 {
1679 s1 += *buf++;
1680 s2 += s1;
1681 }
1682 while (--k);
1683 }
1684
1685 s1 %= A32_BASE;
1686 s2 %= A32_BASE;
1687 }
1688
1689 return (s2 << 16) | s1;
1690}
1691
1692/******************************************************************************************
1693 Run-length function
1694 ******************************************************************************************/
1695
1696static INLINE int
1697xd3_comprun (const uint8_t *seg, int slook, uint8_t *run_cp)
1698{
1699 int i;
1700 int run_l = 0;
1701 uint8_t run_c = 0;
1702
1703 for (i = 0; i < slook; i += 1)
1704 {
1705 NEXTRUN(seg[i]);
1706 }
1707
1708 (*run_cp) = run_c;
1709
1710 return run_l;
1711}
1712
1713/******************************************************************************************
1714 Basic encoder/decoder functions
1715 ******************************************************************************************/
1716
1717static int
1718xd3_decode_byte (xd3_stream *stream, uint *val)
1719{
1720 if (stream->avail_in == 0)
1721 {
1722 stream->msg = "further input required";
1723 return XD3_INPUT;
1724 }
1725
1726 (*val) = stream->next_in[0];
1727
1728 DECODE_INPUT (1);
1729 return 0;
1730}
1731
1732static int
1733xd3_decode_bytes (xd3_stream *stream, uint8_t *buf, usize_t *pos, usize_t size)
1734{
1735 usize_t want;
1736 usize_t take;
1737
1738 /* Note: The case where (*pos == size) happens when a zero-length appheader or code
1739 * table is transmitted, but there is nothing in the standard against that. */
1740
1741 while (*pos < size)
1742 {
1743 if (stream->avail_in == 0)
1744 {
1745 stream->msg = "further input required";
1746 return XD3_INPUT;
1747 }
1748
1749 want = size - *pos;
1750 take = min (want, stream->avail_in);
1751
1752 memcpy (buf + *pos, stream->next_in, take);
1753
1754 DECODE_INPUT (take);
1755 (*pos) += take;
1756 }
1757
1758 return 0;
1759}
1760
1761#if XD3_ENCODER
1762static int
1763xd3_emit_byte (xd3_stream *stream,
1764 xd3_output **outputp,
1765 uint8_t code)
1766{
1767 xd3_output *output = (*outputp);
1768
1769 if (output->next == output->avail)
1770 {
1771 xd3_output *aoutput;
1772
1773 if ((aoutput = xd3_alloc_output (stream, output)) == NULL)
1774 {
1775 return ENOMEM;
1776 }
1777
1778 output = (*outputp) = aoutput;
1779 }
1780
1781 output->base[output->next++] = code;
1782
1783 return 0;
1784}
1785
1786static int
1787xd3_emit_bytes (xd3_stream *stream,
1788 xd3_output **outputp,
1789 const uint8_t *base,
1790 usize_t size)
1791{
1792 xd3_output *output = (*outputp);
1793
1794 do
1795 {
1796 usize_t take;
1797
1798 if (output->next == output->avail)
1799 {
1800 xd3_output *aoutput;
1801
1802 if ((aoutput = xd3_alloc_output (stream, output)) == NULL)
1803 {
1804 return ENOMEM;
1805 }
1806
1807 output = (*outputp) = aoutput;
1808 }
1809
1810 take = min (output->avail - output->next, size);
1811
1812 memcpy (output->base + output->next, base, take);
1813
1814 output->next += take;
1815 size -= take;
1816 base += take;
1817 }
1818 while (size > 0);
1819
1820 return 0;
1821}
1822#endif /* XD3_ENCODER */
1823
1824/******************************************************************************************
1825 Integer encoder/decoder functions
1826 ******************************************************************************************/
1827
1828#define DECODE_INTEGER_TYPE(PART,OFLOW) \
1829 while (stream->avail_in != 0) \
1830 { \
1831 uint next = stream->next_in[0]; \
1832 \
1833 DECODE_INPUT(1); \
1834 \
1835 if (PART & OFLOW) \
1836 { \
1837 stream->msg = "overflow in decode_integer"; \
1838 return XD3_INVALID_INPUT; \
1839 } \
1840 \
1841 PART = (PART << 7) | (next & 127); \
1842 \
1843 if ((next & 128) == 0) \
1844 { \
1845 (*val) = PART; \
1846 PART = 0; \
1847 return 0; \
1848 } \
1849 } \
1850 \
1851 stream->msg = "further input required"; \
1852 return XD3_INPUT
1853
1854#define READ_INTEGER_TYPE(TYPE, OFLOW) \
1855 TYPE val = 0; \
1856 const uint8_t *inp = (*inpp); \
1857 uint next; \
1858 \
1859 do \
1860 { \
1861 if (inp == max) \
1862 { \
1863 stream->msg = "end-of-input in read_integer"; \
1864 return XD3_INVALID_INPUT; \
1865 } \
1866 \
1867 if (val & OFLOW) \
1868 { \
1869 stream->msg = "overflow in read_intger"; \
1870 return XD3_INVALID_INPUT; \
1871 } \
1872 \
1873 next = (*inp++); \
1874 val = (val << 7) | (next & 127); \
1875 } \
1876 while (next & 128); \
1877 \
1878 (*valp) = val; \
1879 (*inpp) = inp; \
1880 \
1881 return 0
1882
1883#define EMIT_INTEGER_TYPE() \
1884 /* max 64-bit value in base-7 encoding is 9.1 bytes */ \
1885 uint8_t buf[10]; \
1886 usize_t bufi = 10; \
1887 \
1888 XD3_ASSERT (num >= 0); \
1889 \
1890 /* This loop performs division and turns on all MSBs. */ \
1891 do \
1892 { \
1893 buf[--bufi] = (num & 127) | 128; \
1894 num >>= 7; \
1895 } \
1896 while (num != 0); \
1897 \
1898 /* Turn off MSB of the last byte. */ \
1899 buf[9] &= 127; \
1900 \
1901 XD3_ASSERT (bufi >= 0); \
1902 \
1903 return xd3_emit_bytes (stream, output, buf + bufi, 10 - bufi)
1904
1905#define IF_SIZEOF32(x) if (num < (1U << (7 * (x)))) return (x);
1906#define IF_SIZEOF64(x) if (num < (1ULL << (7 * (x)))) return (x);
1907
1908#if USE_UINT32
1909static uint
1910xd3_sizeof_uint32_t (uint32_t num)
1911{
1912 IF_SIZEOF32(1);
1913 IF_SIZEOF32(2);
1914 IF_SIZEOF32(3);
1915 IF_SIZEOF32(4);
1916 return 5;
1917}
1918
1919static int
1920xd3_decode_uint32_t (xd3_stream *stream, uint32_t *val)
1921{ DECODE_INTEGER_TYPE (stream->dec_32part, UINT32_OFLOW_MASK); }
1922
1923static int
1924xd3_read_uint32_t (xd3_stream *stream, const uint8_t **inpp, const uint8_t *max, uint32_t *valp)
1925{ READ_INTEGER_TYPE (uint32_t, UINT32_OFLOW_MASK); }
1926
1927#if XD3_ENCODER
1928static int
1929xd3_emit_uint32_t (xd3_stream *stream, xd3_output **output, uint32_t num)
1930{ EMIT_INTEGER_TYPE (); }
1931#endif
1932#endif
1933
1934#if USE_UINT64
1935static int
1936xd3_decode_uint64_t (xd3_stream *stream, uint64_t *val)
1937{ DECODE_INTEGER_TYPE (stream->dec_64part, UINT64_OFLOW_MASK); }
1938
1939#if XD3_ENCODER
1940static int
1941xd3_emit_uint64_t (xd3_stream *stream, xd3_output **output, uint64_t num)
1942{ EMIT_INTEGER_TYPE (); }
1943#endif
1944
1945/* These are tested but not used */
1946#if REGRESSION_TEST
1947static int
1948xd3_read_uint64_t (xd3_stream *stream, const uint8_t **inpp, const uint8_t *max, uint64_t *valp)
1949{ READ_INTEGER_TYPE (uint64_t, UINT64_OFLOW_MASK); }
1950
1951static uint
1952xd3_sizeof_uint64_t (uint64_t num)
1953{
1954 IF_SIZEOF64(1);
1955 IF_SIZEOF64(2);
1956 IF_SIZEOF64(3);
1957 IF_SIZEOF64(4);
1958 IF_SIZEOF64(5);
1959 IF_SIZEOF64(6);
1960 IF_SIZEOF64(7);
1961 IF_SIZEOF64(8);
1962 IF_SIZEOF64(9);
1963
1964 return 10;
1965}
1966#endif
1967
1968#endif
1969
1970/******************************************************************************************
1971 Address cache stuff
1972 ******************************************************************************************/
1973
1974static int
1975xd3_alloc_cache (xd3_stream *stream)
1976{
1977 if (((stream->acache.s_near > 0) &&
1978 (stream->acache.near_array = xd3_alloc (stream, stream->acache.s_near, sizeof (usize_t))) == NULL) ||
1979 ((stream->acache.s_same > 0) &&
1980 (stream->acache.same_array = xd3_alloc (stream, stream->acache.s_same * 256, sizeof (usize_t))) == NULL))
1981 {
1982 return ENOMEM;
1983 }
1984
1985 return 0;
1986}
1987
1988static void
1989xd3_init_cache (xd3_addr_cache* acache)
1990{
1991 if (acache->s_near > 0)
1992 {
1993 memset (acache->near_array, 0, acache->s_near * sizeof (usize_t));
1994 acache->next_slot = 0;
1995 }
1996
1997 if (acache->s_same > 0)
1998 {
1999 memset (acache->same_array, 0, acache->s_same * 256 * sizeof (usize_t));
2000 }
2001}
2002
2003static void
2004xd3_update_cache (xd3_addr_cache* acache, usize_t addr)
2005{
2006 if (acache->s_near > 0)
2007 {
2008 acache->near_array[acache->next_slot] = addr;
2009 acache->next_slot = (acache->next_slot + 1) % acache->s_near;
2010 }
2011
2012 if (acache->s_same > 0)
2013 {
2014 acache->same_array[addr % (acache->s_same*256)] = addr;
2015 }
2016}
2017
2018#if XD3_ENCODER
2019/* OPT: this gets called a lot, can it be optimized? */
2020static int
2021xd3_encode_address (xd3_stream *stream, usize_t addr, usize_t here, uint8_t* mode)
2022{
2023 usize_t d, bestd;
2024 int i, bestm, ret;
2025 xd3_addr_cache* acache = & stream->acache;
2026
2027#define SMALLEST_INT(x) do { if (((x) & ~127) == 0) { goto good; } } while (0)
2028
2029 /* Attempt to find the address mode that yields the smallest integer value for "d", the
2030 * encoded address value, thereby minimizing the encoded size of the address. */
2031 bestd = addr;
2032 bestm = VCD_SELF;
2033
2034 XD3_ASSERT (addr < here);
2035
2036 SMALLEST_INT (bestd);
2037
2038 if ((d = here-addr) < bestd)
2039 {
2040 bestd = d;
2041 bestm = VCD_HERE;
2042
2043 SMALLEST_INT (bestd);
2044 }
2045
2046 for (i = 0; i < acache->s_near; i += 1)
2047 {
2048 d = addr - acache->near_array[i];
2049
2050 if (d >= 0 && d < bestd)
2051 {
2052 bestd = d;
2053 bestm = i+2; /* 2 counts the VCD_SELF, VCD_HERE modes */
2054
2055 SMALLEST_INT (bestd);
2056 }
2057 }
2058
2059 if (acache->s_same > 0 && acache->same_array[d = addr%(acache->s_same*256)] == addr)
2060 {
2061 bestd = d%256;
2062 bestm = acache->s_near + 2 + d/256; /* 2 + s_near offsets past the VCD_NEAR modes */
2063
2064 if ((ret = xd3_emit_byte (stream, & ADDR_TAIL (stream), bestd))) { return ret; }
2065 }
2066 else
2067 {
2068 good:
2069
2070 if ((ret = xd3_emit_size (stream, & ADDR_TAIL (stream), bestd))) { return ret; }
2071 }
2072
2073 xd3_update_cache (acache, addr);
2074
2075 (*mode) += bestm;
2076
2077 return 0;
2078}
2079#endif
2080
2081static int
2082xd3_decode_address (xd3_stream *stream, usize_t here, uint mode, const uint8_t **inpp, const uint8_t *max, uint32_t *valp)
2083{
2084 int ret;
2085 uint same_start = 2 + stream->acache.s_near;
2086
2087 if (mode < same_start)
2088 {
2089 if ((ret = xd3_read_size (stream, inpp, max, valp))) { return ret; }
2090
2091 switch (mode)
2092 {
2093 case VCD_SELF:
2094 break;
2095 case VCD_HERE:
2096 (*valp) = here - (*valp);
2097 break;
2098 default:
2099 (*valp) += stream->acache.near_array[mode - 2];
2100 break;
2101 }
2102 }
2103 else
2104 {
2105 if (*inpp == max)
2106 {
2107 stream->msg = "address underflow";
2108 return XD3_INVALID_INPUT;
2109 }
2110
2111 mode -= same_start;
2112
2113 (*valp) = stream->acache.same_array[mode*256 + (**inpp)];
2114
2115 (*inpp) += 1;
2116 }
2117
2118 xd3_update_cache (& stream->acache, *valp);
2119
2120 return 0;
2121}
2122
2123/******************************************************************************************
2124 Alloc/free
2125 ******************************************************************************************/
2126
2127static void*
2128__xd3_alloc_func (void* opaque, usize_t items, usize_t size)
2129{
2130 return malloc (items * size);
2131}
2132
2133static void
2134__xd3_free_func (void* opaque, void* address)
2135{
2136 free (address);
2137}
2138
2139static void*
2140xd3_alloc (xd3_stream *stream,
2141 usize_t elts,
2142 usize_t size)
2143{
2144 void *a = stream->alloc (stream->opaque, elts, size);
2145
2146 if (a != NULL)
2147 {
2148 IF_DEBUG (stream->alloc_cnt += 1);
2149 }
2150 else
2151 {
2152 stream->msg = "out of memory";
2153 }
2154
2155 return a;
2156}
2157
2158static void
2159xd3_free (xd3_stream *stream,
2160 void *ptr)
2161{
2162 if (ptr != NULL)
2163 {
2164 IF_DEBUG (stream->free_cnt += 1);
2165 XD3_ASSERT (stream->free_cnt <= stream->alloc_cnt);
2166 stream->free (stream->opaque, ptr);
2167 }
2168}
2169
2170#if XD3_ENCODER
2171static void*
2172xd3_alloc0 (xd3_stream *stream,
2173 usize_t elts,
2174 usize_t size)
2175{
2176 void *a = xd3_alloc (stream, elts, size);
2177
2178 if (a != NULL)
2179 {
2180 memset (a, 0, elts * size);
2181 }
2182
2183 return a;
2184}
2185
2186static xd3_output*
2187xd3_alloc_output (xd3_stream *stream,
2188 xd3_output *old_output)
2189{
2190 xd3_output *output;
2191 uint8_t *base;
2192
2193 if (stream->enc_free != NULL)
2194 {
2195 output = stream->enc_free;
2196 stream->enc_free = output->next_page;
2197 }
2198 else
2199 {
2200 if ((output = xd3_alloc (stream, 1, sizeof (xd3_output))) == NULL)
2201 {
2202 return NULL;
2203 }
2204
2205 if ((base = xd3_alloc (stream, XD3_ALLOCSIZE, sizeof (uint8_t))) == NULL)
2206 {
2207 xd3_free (stream, output);
2208 return NULL;
2209 }
2210
2211 output->base = base;
2212 output->avail = XD3_ALLOCSIZE;
2213 }
2214
2215 output->next = 0;
2216
2217 if (old_output)
2218 {
2219 old_output->next_page = output;
2220 }
2221
2222 output->next_page = NULL;
2223
2224 return output;
2225}
2226
2227static usize_t
2228xd3_sizeof_output (xd3_output *output)
2229{
2230 usize_t s = 0;
2231
2232 for (; output; output = output->next_page)
2233 {
2234 s += output->next;
2235 }
2236
2237 return s;
2238}
2239
2240static void
2241xd3_freelist_output (xd3_stream *stream,
2242 xd3_output *output)
2243{
2244 xd3_output *tmp;
2245
2246 while (output)
2247 {
2248 tmp = output;
2249 output = output->next_page;
2250
2251 tmp->next = 0;
2252 tmp->next_page = stream->enc_free;
2253 stream->enc_free = tmp;
2254 }
2255}
2256
2257static void
2258xd3_free_output (xd3_stream *stream,
2259 xd3_output *output)
2260{
2261 xd3_output *next;
2262
2263 again:
2264 if (output == NULL)
2265 {
2266 return;
2267 }
2268
2269 next = output->next_page;
2270
2271 xd3_free (stream, output->base);
2272 xd3_free (stream, output);
2273
2274 output = next;
2275 goto again;
2276}
2277#endif /* XD3_ENCODER */
2278
2279void
2280xd3_free_stream (xd3_stream *stream)
2281{
2282 xd3_iopt_buflist *blist = stream->iopt_alloc;
2283
2284 while (blist != NULL)
2285 {
2286 xd3_iopt_buflist *tmp = blist;
2287 blist = blist->next;
2288 xd3_free (stream, tmp->buffer);
2289 xd3_free (stream, tmp);
2290 }
2291
2292 xd3_free (stream, stream->large_table);
2293 xd3_free (stream, stream->small_table);
2294 xd3_free (stream, stream->small_prev);
2295
2296#if XD3_ENCODER
2297 {
2298 int i;
2299 for (i = 0; i < ENC_SECTS; i += 1)
2300 {
2301 xd3_free_output (stream, stream->enc_heads[i]);
2302 }
2303 xd3_free_output (stream, stream->enc_free);
2304 }
2305#endif
2306
2307 xd3_free (stream, stream->acache.near_array);
2308 xd3_free (stream, stream->acache.same_array);
2309
2310 xd3_free (stream, stream->inst_sect.copied1);
2311 xd3_free (stream, stream->addr_sect.copied1);
2312 xd3_free (stream, stream->data_sect.copied1);
2313
2314 xd3_free (stream, stream->dec_buffer);
2315 xd3_free (stream, (uint8_t*) stream->dec_lastwin);
2316
2317 xd3_free (stream, stream->buf_in);
2318 xd3_free (stream, stream->dec_appheader);
2319 xd3_free (stream, stream->dec_codetbl);
2320 xd3_free (stream, stream->code_table_alloc);
2321
2322#if SECONDARY_ANY
2323 xd3_free (stream, stream->inst_sect.copied2);
2324 xd3_free (stream, stream->addr_sect.copied2);
2325 xd3_free (stream, stream->data_sect.copied2);
2326
2327 if (stream->sec_type != NULL)
2328 {
2329 stream->sec_type->destroy (stream, stream->sec_stream_d);
2330 stream->sec_type->destroy (stream, stream->sec_stream_i);
2331 stream->sec_type->destroy (stream, stream->sec_stream_a);
2332 }
2333#endif
2334
2335 XD3_ASSERT (stream->alloc_cnt == stream->free_cnt);
2336
2337 memset (stream, 0, sizeof (xd3_stream));
2338}
2339
2340#if (XD3_DEBUG > 1 || VCDIFF_TOOLS)
2341static const char*
2342xd3_rtype_to_string (xd3_rtype type, int print_mode)
2343{
2344 switch (type)
2345 {
2346 case XD3_NOOP:
2347 return "NOOP ";
2348 case XD3_RUN:
2349 return "RUN ";
2350 case XD3_ADD:
2351 return "ADD ";
2352 default: break;
2353 }
2354 if (! print_mode)
2355 {
2356 return "CPY ";
2357 }
2358 switch (type)
2359 {
2360 case XD3_CPY + 0: return "CPY_0";
2361 case XD3_CPY + 1: return "CPY_1";
2362 case XD3_CPY + 2: return "CPY_2";
2363 case XD3_CPY + 3: return "CPY_3";
2364 case XD3_CPY + 4: return "CPY_4";
2365 case XD3_CPY + 5: return "CPY_5";
2366 case XD3_CPY + 6: return "CPY_6";
2367 case XD3_CPY + 7: return "CPY_7";
2368 case XD3_CPY + 8: return "CPY_8";
2369 case XD3_CPY + 9: return "CPY_9";
2370 default: return "CPY>9";
2371 }
2372}
2373#endif
2374
2375/******************************************************************************************
2376 Stream configuration
2377 ******************************************************************************************/
2378
2379int
2380xd3_config_stream(xd3_stream *stream,
2381 xd3_config *config)
2382{
2383 int ret;
2384 xd3_config defcfg;
2385 xd3_smatcher *smatcher = &stream->smatcher;
2386
2387 if (config == NULL)
2388 {
2389 config = & defcfg;
2390 memset (config, 0, sizeof (*config));
2391 }
2392
2393 /* Initial setup: no error checks yet */
2394 memset (stream, 0, sizeof (*stream));
2395
2396 stream->winsize = config->winsize ? config->winsize : XD3_DEFAULT_WINSIZE;
2397 stream->sprevsz = config->sprevsz ? config->sprevsz : XD3_DEFAULT_SPREVSZ;
2398 stream->srcwin_maxsz = config->srcwin_maxsz ? config->srcwin_maxsz : XD3_DEFAULT_SRCWINSZ;
2399
2400 if (config->iopt_size == 0)
2401 {
2402 stream->iopt_size = XD3_ALLOCSIZE / sizeof(xd3_rinst);
2403 stream->iopt_unlimited = 1;
2404 }
2405 else
2406 {
2407 stream->iopt_size = config->iopt_size;
2408 }
2409
2410 stream->getblk = config->getblk;
2411 stream->alloc = config->alloc ? config->alloc : __xd3_alloc_func;
2412 stream->free = config->freef ? config->freef : __xd3_free_func;
2413 stream->opaque = config->opaque;
2414 stream->flags = config->flags;
2415
2416 /* Secondary setup. */
2417 stream->sec_data = config->sec_data;
2418 stream->sec_inst = config->sec_inst;
2419 stream->sec_addr = config->sec_addr;
2420
2421 stream->sec_data.data_type = DATA_SECTION;
2422 stream->sec_inst.data_type = INST_SECTION;
2423 stream->sec_addr.data_type = ADDR_SECTION;
2424
2425 /* Check static sizes. */
2426 if (sizeof (usize_t) != SIZEOF_USIZE_T ||
2427 sizeof (xoff_t) != SIZEOF_XOFF_T ||
2428 (ret = xd3_check_pow2(XD3_ALLOCSIZE, NULL)))
2429 {
2430 stream->msg = "incorrect compilation: wrong integer sizes";
2431 return XD3_INTERNAL;
2432 }
2433
2434 /* Check/set secondary compressor. */
2435 switch (stream->flags & XD3_SEC_TYPE)
2436 {
2437 case 0:
2438 if (stream->flags & XD3_SEC_OTHER)
2439 {
2440 stream->msg = "XD3_SEC flags require a secondary compressor type";
2441 return XD3_INTERNAL;
2442 }
2443 break;
2444 case XD3_SEC_FGK:
2445 FGK_CASE (stream);
2446 case XD3_SEC_DJW:
2447 DJW_CASE (stream);
2448 default:
2449 stream->msg = "too many secondary compressor types set";
2450 return XD3_INTERNAL;
2451 }
2452
2453 /* Check/set encoder code table. */
2454 switch (stream->flags & XD3_ALT_CODE_TABLE) {
2455 case 0:
2456 stream->code_table_desc = & __rfc3284_code_table_desc;
2457 stream->code_table_func = xd3_rfc3284_code_table;
2458 break;
2459#if GENERIC_ENCODE_TABLES
2460 case XD3_ALT_CODE_TABLE:
2461 stream->code_table_desc = & __alternate_code_table_desc;
2462 stream->code_table_func = xd3_alternate_code_table;
2463 stream->comp_table_func = xd3_compute_alternate_table_encoding;
2464 break;
2465#endif
2466 default:
2467 stream->msg = "alternate code table support was not compiled";
2468 return XD3_INTERNAL;
2469 }
2470
2471 /* Check sprevsz */
2472 if (smatcher->small_chain == 1)
2473 {
2474 stream->sprevsz = 0;
2475 }
2476 else
2477 {
2478 if ((ret = xd3_check_pow2 (stream->sprevsz, NULL)))
2479 {
2480 stream->msg = "sprevsz is required to be a power of two";
2481 return XD3_INTERNAL;
2482 }
2483
2484 stream->sprevmask = stream->sprevsz - 1;
2485 }
2486
2487 /* Default scanner settings. */
2488 switch (config->smatch_cfg)
2489 {
2490 IF_BUILD_SOFT(case XD3_SMATCH_SOFT:
2491 {
2492 *smatcher = config->smatcher_soft;
2493 smatcher->string_match = __smatcher_soft.string_match;
2494 smatcher->name = __smatcher_soft.name;
2495 if (smatcher->large_look < MIN_MATCH ||
2496 smatcher->large_step < 1 ||
2497 smatcher->small_look < MIN_MATCH)
2498 {
2499 stream->msg = "invalid soft string-match config";
2500 return XD3_INVALID;
2501 }
2502 break;
2503 })
2504
2505 IF_BUILD_DEFAULT(case XD3_SMATCH_DEFAULT:
2506 *smatcher = __smatcher_default;
2507 break;)
2508 IF_BUILD_SLOW(case XD3_SMATCH_SLOW:
2509 *smatcher = __smatcher_slow;
2510 break;)
2511 IF_BUILD_FASTEST(case XD3_SMATCH_FASTEST:
2512 *smatcher = __smatcher_fastest;
2513 break;)
2514 IF_BUILD_FAST(case XD3_SMATCH_FAST:
2515 *smatcher = __smatcher_fast;
2516 break;)
2517 default:
2518 stream->msg = "invalid string match config type";
2519 return XD3_INTERNAL;
2520 }
2521
2522 if (config->smatch_cfg == XD3_SMATCH_DEFAULT &&
2523 (stream->flags & XD3_COMPLEVEL_MASK) != 0)
2524 {
2525 int level = (stream->flags & XD3_COMPLEVEL_MASK) >> XD3_COMPLEVEL_SHIFT;
2526
2527 switch (level)
2528 {
2529 case 1: case 2:
2530 IF_BUILD_FASTEST(*smatcher = __smatcher_fastest;
2531 break;)
2532 case 3: case 4: case 5:
2533 IF_BUILD_FAST(*smatcher = __smatcher_fast;
2534 break;)
2535 case 6:
2536 IF_BUILD_DEFAULT(*smatcher = __smatcher_default;
2537 break;)
2538 default:
2539 IF_BUILD_SLOW(*smatcher = __smatcher_slow;
2540 break;)
2541 }
2542 }
2543
2544 return 0;
2545}
2546
2547/******************************************************************************************
2548 Getblk interface
2549 ******************************************************************************************/
2550
2551/* This function interfaces with the client getblk function, checks its results, etc. */
2552static int
2553xd3_getblk (xd3_stream *stream/*, xd3_source *source*/, xoff_t blkno)
2554{
2555 int ret;
2556 xd3_source *source = stream->src;
2557
2558 if (blkno >= source->blocks)
2559 {
2560 IF_DEBUG1 (DP(RINT "[getblk] block %"Q"u\n", blkno));
2561 stream->msg = "source file too short";
2562 return XD3_INTERNAL;
2563 }
2564
2565 if (blkno != source->curblkno || source->curblk == NULL)
2566 {
2567 XD3_ASSERT (source->curblk != NULL || blkno != source->curblkno);
2568
2569 source->getblkno = blkno;
2570
2571 if (stream->getblk == NULL)
2572 {
2573 stream->msg = "getblk source input";
2574 return XD3_GETSRCBLK;
2575 }
2576 else if ((ret = stream->getblk (stream, source, blkno)) != 0)
2577 {
2578 stream->msg = "getblk failed";
2579 return ret;
2580 }
2581
2582 XD3_ASSERT (source->curblk != NULL);
2583 }
2584
2585 if (source->onblk != xd3_bytes_on_srcblk (source, blkno))
2586 {
2587 stream->msg = "getblk returned short block";
2588 return XD3_INTERNAL;
2589 }
2590
2591 return 0;
2592}
2593
2594/******************************************************************************************
2595 Stream open/close
2596 ******************************************************************************************/
2597
2598int
2599xd3_set_source (xd3_stream *stream,
2600 xd3_source *src)
2601{
2602 xoff_t blk_num;
2603 xoff_t tail_size;
2604
2605 IF_DEBUG1 (DP(RINT "[set source] size %"Q"u\n", src->size));
2606
2607 if (src == NULL || src->size < stream->smatcher.large_look) { return 0; }
2608
2609 stream->src = src;
2610 blk_num = src->size / src->blksize;
2611 tail_size = src->size % src->blksize;
2612 src->blocks = blk_num + (tail_size > 0);
2613 src->srclen = 0;
2614 src->srcbase = 0;
2615
2616 return 0;
2617}
2618
2619void
2620xd3_abort_stream (xd3_stream *stream)
2621{
2622 stream->dec_state = DEC_ABORTED;
2623 stream->enc_state = ENC_ABORTED;
2624}
2625
2626int
2627xd3_close_stream (xd3_stream *stream)
2628{
2629 if (stream->enc_state != 0 && stream->enc_state != ENC_ABORTED)
2630 {
2631 /* If encoding, should be ready for more input but not actually have any. */
2632 if (stream->enc_state != ENC_INPUT || stream->avail_in != 0)
2633 {
2634 stream->msg = "encoding is incomplete";
2635 return XD3_INTERNAL;
2636 }
2637 }
2638 else
2639 {
2640 switch (stream->dec_state)
2641 {
2642 case DEC_VCHEAD:
2643 case DEC_WININD:
2644 /* TODO: Address the zero-byte ambiguity. Does the encoder emit a window or
2645 * not? If so, then catch an error here. If not, need another routine to say
2646 * decode_at_least_one_if_empty. */
2647 case DEC_ABORTED:
2648 break;
2649 default:
2650 /* If decoding, should be ready for the next window. */
2651 stream->msg = "EOF in decode";
2652 return XD3_INTERNAL;
2653 }
2654 }
2655
2656 return 0;
2657}
2658
2659/******************************************************************************************
2660 Application header
2661 ******************************************************************************************/
2662
2663int
2664xd3_get_appheader (xd3_stream *stream,
2665 uint8_t **data,
2666 usize_t *size)
2667{
2668 if (stream->dec_state < DEC_WININD)
2669 {
2670 stream->msg = "application header not available";
2671 return XD3_INTERNAL;
2672 }
2673
2674 (*data) = stream->dec_appheader;
2675 (*size) = stream->dec_appheadsz;
2676 return 0;
2677}
2678
2679/******************************************************************************************
2680 Decoder stuff
2681 ******************************************************************************************/
2682
2683#include "xdelta3-decode.h"
2684
2685/******************************************************************************************
2686 Encoder stuff
2687 ******************************************************************************************/
2688
2689#if XD3_ENCODER
2690void
2691xd3_set_appheader (xd3_stream *stream,
2692 const uint8_t *data,
2693 usize_t size)
2694{
2695 stream->enc_appheader = data;
2696 stream->enc_appheadsz = size;
2697}
2698
2699#if XD3_DEBUG
2700static int
2701xd3_iopt_check (xd3_stream *stream)
2702{
2703 int ul = xd3_rlist_length (& stream->iopt_used);
2704 int fl = xd3_rlist_length (& stream->iopt_free);
2705
2706 return (ul + fl + (stream->iout ? 1 : 0)) == stream->iopt_size;
2707}
2708#endif
2709
2710static xd3_rinst*
2711xd3_iopt_free (xd3_stream *stream, xd3_rinst *i)
2712{
2713 xd3_rinst *n = xd3_rlist_remove (i);
2714 xd3_rlist_push_back (& stream->iopt_free, i);
2715 return n;
2716}
2717
2718static void
2719xd3_iopt_free_nonadd (xd3_stream *stream, xd3_rinst *i)
2720{
2721 if (i->type != XD3_ADD)
2722 {
2723 xd3_rlist_push_back (& stream->iopt_free, i);
2724 }
2725}
2726
2727/* When an instruction is ready to flush from the iopt buffer, this function is called to
2728 * produce an encoding. It writes the instruction plus size, address, and data to the
2729 * various encoding sections. */
2730static int
2731xd3_iopt_finish_encoding (xd3_stream *stream, xd3_rinst *inst)
2732{
2733 int ret;
2734
2735 /* Check for input overflow. */
2736 XD3_ASSERT (inst->pos + inst->size <= stream->avail_in);
2737
2738 switch (inst->type)
2739 {
2740 case XD3_CPY:
2741 {
2742 /* the address may have an offset if there is a source window. */
2743 usize_t addr;
2744 xd3_source *src = stream->src;
2745
2746 if (src != NULL)
2747 {
2748 /* If there is a source copy, the source must have its source window decided
2749 * before we can encode. This can be bad -- we have to make this decision
2750 * even if no source matches have been found. */
2751 if (stream->srcwin_decided == 0)
2752 {
2753 if ((ret = xd3_srcwin_setup (stream))) { return ret; }
2754 }
2755
2756 /* xtra field indicates the copy is from the source */
2757 if (inst->xtra)
2758 {
2759 XD3_ASSERT (inst->addr >= src->srcbase);
2760 XD3_ASSERT (inst->addr + inst->size <= src->srcbase + src->srclen);
2761 addr = (inst->addr - src->srcbase);
2762 stream->n_scpy += 1;
2763 stream->l_scpy += inst->size;
2764 }
2765 else
2766 {
2767 /* with source window: target copy address is offset by taroff. */
2768 addr = stream->taroff + (usize_t) inst->addr;
2769 stream->n_tcpy += 1;
2770 stream->l_tcpy += inst->size;
2771 }
2772 }
2773 else
2774 {
2775 addr = (usize_t) inst->addr;
2776 stream->n_tcpy += 1;
2777 stream->l_tcpy += inst->size;
2778 }
2779
2780 XD3_ASSERT (inst->size >= MIN_MATCH);
2781
2782 /* the "here" position is always offset by taroff */
2783 if ((ret = xd3_encode_address (stream, addr, inst->pos + stream->taroff, & inst->type)))
2784 {
2785 return ret;
2786 }
2787
2788 IF_DEBUG1 ({
2789 static int cnt;
2790 DP(RINT "[iopt copy:%d] pos %"Q"u-%"Q"u addr %"Q"u-%"Q"u size %u\n",
2791 cnt++,
2792 stream->total_in + inst->pos,
2793 stream->total_in + inst->pos + inst->size,
2794 inst->addr, inst->addr + inst->size, inst->size);
2795 });
2796 break;
2797 }
2798 case XD3_RUN:
2799 {
2800 XD3_ASSERT (inst->size >= MIN_MATCH);
2801
2802 if ((ret = xd3_emit_byte (stream, & DATA_TAIL (stream), inst->xtra))) { return ret; }
2803
2804 stream->n_run += 1;
2805 stream->l_run += inst->size;
2806
2807 IF_DEBUG1 ({
2808 static int cnt;
2809 DP(RINT "[iopt run:%d] pos %"Q"u size %u\n", cnt++, stream->total_in + inst->pos, inst->size);
2810 });
2811 break;
2812 }
2813 case XD3_ADD:
2814 {
2815 if ((ret = xd3_emit_bytes (stream, & DATA_TAIL (stream),
2816 stream->next_in + inst->pos, inst->size))) { return ret; }
2817
2818 stream->n_add += 1;
2819 stream->l_add += inst->size;
2820
2821 IF_DEBUG1 ({
2822 static int cnt;
2823 DP(RINT "[iopt add:%d] pos %"Q"u size %u\n", cnt++, stream->total_in + inst->pos, inst->size);
2824 });
2825
2826 break;
2827 }
2828 }
2829
2830 /* This is the only place stream->unencoded_offset is incremented. */
2831 XD3_ASSERT (stream->unencoded_offset == inst->pos);
2832 stream->unencoded_offset += inst->size;
2833
2834 IF_DEBUG (stream->n_emit += inst->size);
2835
2836 inst->code2 = 0;
2837
2838 XD3_CHOOSE_INSTRUCTION (stream, stream->iout, inst);
2839
2840 if (stream->iout != NULL)
2841 {
2842 if (stream->iout->code2 != 0)
2843 {
2844 if ((ret = xd3_emit_double (stream, stream->iout, inst, stream->iout->code2))) { return ret; }
2845
2846 xd3_iopt_free_nonadd (stream, stream->iout);
2847 xd3_iopt_free_nonadd (stream, inst);
2848 stream->iout = NULL;
2849 return 0;
2850 }
2851 else
2852 {
2853 if ((ret = xd3_emit_single (stream, stream->iout, stream->iout->code1))) { return ret; }
2854
2855 xd3_iopt_free_nonadd (stream, stream->iout);
2856 }
2857 }
2858
2859 stream->iout = inst;
2860
2861 return 0;
2862}
2863
2864/* This possibly encodes an add instruction, iadd, which must remain on the stack until
2865 * the following call to xd3_iopt_finish_encoding. */
2866static int
2867xd3_iopt_add (xd3_stream *stream, usize_t pos, xd3_rinst *iadd)
2868{
2869 int ret;
2870 usize_t off = stream->unencoded_offset;
2871
2872 if (pos > off)
2873 {
2874 iadd->type = XD3_ADD;
2875 iadd->pos = off;
2876 iadd->size = pos - off;
2877
2878 if ((ret = xd3_iopt_finish_encoding (stream, iadd))) { return ret; }
2879 }
2880
2881 return 0;
2882}
2883
2884/* This function calls xd3_iopt_finish_encoding to finish encoding an instruction, and it
2885 * may also produce an add instruction for an unmatched region. */
2886static int
2887xd3_iopt_add_encoding (xd3_stream *stream, xd3_rinst *inst)
2888{
2889 int ret;
2890 xd3_rinst iadd;
2891
2892 if ((ret = xd3_iopt_add (stream, inst->pos, & iadd))) { return ret; }
2893
2894 if ((ret = xd3_iopt_finish_encoding (stream, inst))) { return ret; }
2895
2896 return 0;
2897}
2898
2899/* Generates a final add instruction to encode the remaining input. */
2900static int
2901xd3_iopt_add_finalize (xd3_stream *stream)
2902{
2903 int ret;
2904 xd3_rinst iadd;
2905
2906 if ((ret = xd3_iopt_add (stream, stream->avail_in, & iadd))) { return ret; }
2907
2908 if (stream->iout)
2909 {
2910 if ((ret = xd3_emit_single (stream, stream->iout, stream->iout->code1))) { return ret; }
2911
2912 xd3_iopt_free_nonadd (stream, stream->iout);
2913 stream->iout = NULL;
2914 }
2915
2916 return 0;
2917}
2918
2919/* Compact the instruction buffer by choosing the best non-overlapping instructions when
2920 * lazy string-matching. There are no ADDs in the iopt buffer because those are
2921 * synthesized in xd3_iopt_add_encoding and during xd3_iopt_add_finalize. */
2922static int
2923xd3_iopt_flush_instructions (xd3_stream *stream, int force)
2924{
2925 xd3_rinst *r1 = xd3_rlist_front (& stream->iopt_used);
2926 xd3_rinst *r2;
2927 xd3_rinst *r3;
2928 usize_t r1end;
2929 usize_t r2end;
2930 usize_t r2off;
2931 usize_t r2moff;
2932 usize_t gap;
2933 usize_t flushed;
2934 int ret;
2935
2936 XD3_ASSERT (xd3_iopt_check (stream));
2937
2938 /* Note: once tried to skip this step if it's possible to assert there are no
2939 * overlapping instructions. Doesn't work because xd3_opt_erase leaves overlapping
2940 * instructions. */
2941 while (! xd3_rlist_end (& stream->iopt_used, r1) &&
2942 ! xd3_rlist_end (& stream->iopt_used, r2 = xd3_rlist_next (r1)))
2943 {
2944 r1end = r1->pos + r1->size;
2945
2946 /* If the instructions do not overlap, continue. */
2947 if (r1end <= r2->pos)
2948 {
2949 r1 = r2;
2950 continue;
2951 }
2952
2953 r2end = r2->pos + r2->size;
2954
2955 /* The min_match adjustments prevent this. */
2956 XD3_ASSERT (r2end > (r1end + LEAST_MATCH_INCR));
2957
2958 /* If r3 is available... */
2959 if (! xd3_rlist_end (& stream->iopt_used, r3 = xd3_rlist_next (r2)))
2960 {
2961 /* If r3 starts before r1 finishes or just about, r2 is irrelevant */
2962 if (r3->pos <= r1end + 1)
2963 {
2964 xd3_iopt_free (stream, r2);
2965 continue;
2966 }
2967 }
2968 else if (! force)
2969 {
2970 /* Unless force, end the loop when r3 is not available. */
2971 break;
2972 }
2973
2974 r2off = r2->pos - r1->pos;
2975 r2moff = r2end - r1end;
2976 gap = r2end - r1->pos;
2977
2978 /* If the two matches overlap almost entirely, choose the better match and discard
2979 * the other. This heuristic is BLACK MAGIC. Havesomething better? */
2980 if (gap < 2*MIN_MATCH || r2moff <= 2 || r2off <= 2)
2981 {
2982 /* Only one match should be used, choose the longer one. */
2983 if (r1->size < r2->size)
2984 {
2985 xd3_iopt_free (stream, r1);
2986 r1 = r2;
2987 }
2988 else
2989 {
2990 /* We are guaranteed that r1 does not overlap now, so advance past r2 */
2991 r1 = xd3_iopt_free (stream, r2);
2992 }
2993 continue;
2994 }
2995 else
2996 {
2997 /* Shorten one of the instructions -- could be optimized based on the address
2998 * cache. */
2999 usize_t average;
3000 usize_t newsize;
3001 usize_t adjust1;
3002
3003 XD3_ASSERT (r1end > r2->pos && r2end > r1->pos);
3004
3005 /* Try to balance the length of both instructions, but avoid making both longer
3006 * than MAX_MATCH_SPLIT . */
3007 average = (gap) / 2;
3008 newsize = min (MAX_MATCH_SPLIT, gap - average);
3009
3010 /* Should be possible to simplify this code. */
3011 if (newsize > r1->size)
3012 {
3013 /* shorten r2 */
3014 adjust1 = r1end - r2->pos;
3015 }
3016 else if (newsize > r2->size)
3017 {
3018 /* shorten r1 */
3019 adjust1 = r1end - r2->pos;
3020
3021 XD3_ASSERT (r1->size > adjust1);
3022
3023 r1->size -= adjust1;
3024
3025 /* don't shorten r2 */
3026 adjust1 = 0;
3027 }
3028 else
3029 {
3030 /* shorten r1 */
3031 adjust1 = r1->size - newsize;
3032
3033 if (r2->pos > r1end - adjust1)
3034 {
3035 adjust1 -= r2->pos - (r1end - adjust1);
3036 }
3037
3038 XD3_ASSERT (r1->size > adjust1);
3039
3040 r1->size -= adjust1;
3041
3042 /* shorten r2 */
3043 XD3_ASSERT (r1->pos + r1->size >= r2->pos);
3044
3045 adjust1 = r1->pos + r1->size - r2->pos;
3046 }
3047
3048 /* Fallthrough above if-else, shorten r2 */
3049 XD3_ASSERT (r2->size > adjust1);
3050
3051 r2->size -= adjust1;
3052 r2->pos += adjust1;
3053 r2->addr += adjust1;
3054
3055 XD3_ASSERT (r1->size >= MIN_MATCH);
3056 XD3_ASSERT (r2->size >= MIN_MATCH);
3057
3058 r1 = r2;
3059 }
3060 }
3061
3062 XD3_ASSERT (xd3_iopt_check (stream));
3063
3064 /* If forcing, pick instructions until the list is empty, otherwise this empties 50% of
3065 * the queue. */
3066 for (flushed = 0; ! xd3_rlist_empty (& stream->iopt_used); )
3067 {
3068 xd3_rinst *renc = xd3_rlist_pop_front (& stream->iopt_used);
3069 if ((ret = xd3_iopt_add_encoding (stream, renc)))
3070 {
3071 return ret;
3072 }
3073
3074 if (! force)
3075 {
3076 if (++flushed > stream->iopt_size / 2)
3077 {
3078 break;
3079 }
3080
3081 /* If there are only two instructions remaining, break, because they were
3082 * not optimized. This means there were more than 50% eliminated by the
3083 * loop above. */
3084 r1 = xd3_rlist_front (& stream->iopt_used);
3085 if (xd3_rlist_end(& stream->iopt_used, r1) ||
3086 xd3_rlist_end(& stream->iopt_used, r2 = xd3_rlist_next (r1)) ||
3087 xd3_rlist_end(& stream->iopt_used, r3 = xd3_rlist_next (r2)))
3088 {
3089 break;
3090 }
3091 }
3092 }
3093
3094 XD3_ASSERT (xd3_iopt_check (stream));
3095
3096 XD3_ASSERT (!force || xd3_rlist_length (& stream->iopt_used) == 0);
3097
3098 return 0;
3099}
3100
3101static int
3102xd3_iopt_get_slot (xd3_stream *stream, xd3_rinst** iptr)
3103{
3104 xd3_rinst *i;
3105 int ret;
3106
3107 if (xd3_rlist_empty (& stream->iopt_free))
3108 {
3109 if (stream->iopt_unlimited)
3110 {
3111 int elts = XD3_ALLOCSIZE / sizeof(xd3_rinst);
3112
3113 if ((ret = xd3_alloc_iopt (stream, elts)))
3114 {
3115 return ret;
3116 }
3117
3118 stream->iopt_size += elts;
3119 }
3120 else
3121 {
3122 if ((ret = xd3_iopt_flush_instructions (stream, 0))) { return ret; }
3123
3124 XD3_ASSERT (! xd3_rlist_empty (& stream->iopt_free));
3125 }
3126 }
3127
3128 i = xd3_rlist_pop_back (& stream->iopt_free);
3129
3130 xd3_rlist_push_back (& stream->iopt_used, i);
3131
3132 (*iptr) = i;
3133
3134 ++stream->i_slots_used;
3135
3136 return 0;
3137}
3138
3139/* A copy is about to be emitted that extends backwards to POS, therefore it may
3140 * completely cover some existing instructions in the buffer. If an instruction is
3141 * completely covered by this new match, erase it. If the new instruction is covered by
3142 * the previous one, return 1 to skip it. */
3143static void
3144xd3_iopt_erase (xd3_stream *stream, usize_t pos, usize_t size)
3145{
3146 while (! xd3_rlist_empty (& stream->iopt_used))
3147 {
3148 xd3_rinst *r = xd3_rlist_back (& stream->iopt_used);
3149
3150 /* Verify that greedy is working. The previous instruction should end before the
3151 * new one begins. */
3152 XD3_ASSERT ((stream->flags & XD3_BEGREEDY) == 0 || (r->pos + r->size <= pos));
3153 /* Verify that min_match is working. The previous instruction should end before the
3154 * new one ends. */
3155 XD3_ASSERT ((stream->flags & XD3_BEGREEDY) != 0 || (r->pos + r->size < pos + size));
3156
3157 /* See if the last instruction starts before the new instruction. If so, there is
3158 * nothing to erase. */
3159 if (r->pos < pos)
3160 {
3161 return;
3162 }
3163
3164 /* Otherwise, the new instruction covers the old one, delete it and repeat. */
3165 xd3_rlist_remove (r);
3166 xd3_rlist_push_back (& stream->iopt_free, r);
3167 --stream->i_slots_used;
3168 }
3169}
3170
3171/* This function tells the last matched input position. */
3172static usize_t
3173xd3_iopt_last_matched (xd3_stream *stream)
3174{
3175 xd3_rinst *r;
3176
3177 if (xd3_rlist_empty (& stream->iopt_used))
3178 {
3179 return 0;
3180 }
3181
3182 r = xd3_rlist_back (& stream->iopt_used);
3183
3184 return r->pos + r->size;
3185}
3186
3187/******************************************************************************************
3188 Emit routines
3189 ******************************************************************************************/
3190
3191static int
3192xd3_emit_single (xd3_stream *stream, xd3_rinst *single, uint code)
3193{
3194 int has_size = stream->code_table[code].size1 == 0;
3195 int ret;
3196
3197 IF_DEBUG1 (DP(RINT "[emit1] %u %s (%u) code %u\n",
3198 single->pos,
3199 xd3_rtype_to_string (single->type, 0),
3200 single->size,
3201 code));
3202
3203 if ((ret = xd3_emit_byte (stream, & INST_TAIL (stream), code))) { return ret; }
3204
3205 if (has_size)
3206 {
3207 if ((ret = xd3_emit_size (stream, & INST_TAIL (stream), single->size))) { return ret; }
3208 }
3209
3210 return 0;
3211}
3212
3213static int
3214xd3_emit_double (xd3_stream *stream, xd3_rinst *first, xd3_rinst *second, uint code)
3215{
3216 int ret;
3217
3218 /* All double instructions use fixed sizes, so all we need to do is output the
3219 * instruction code, no sizes. */
3220 XD3_ASSERT (stream->code_table[code].size1 != 0 &&
3221 stream->code_table[code].size2 != 0);
3222
3223 if ((ret = xd3_emit_byte (stream, & INST_TAIL (stream), code))) { return ret; }
3224
3225 IF_DEBUG1 (DP(RINT "[emit2]: %u %s (%u) %s (%u) code %u\n",
3226 first->pos,
3227 xd3_rtype_to_string (first->type, 0),
3228 first->size,
3229 xd3_rtype_to_string (second->type, 0),
3230 second->size,
3231 code));
3232
3233 return 0;
3234}
3235
3236/* This enters a potential run instruction into the iopt buffer. The position argument is
3237 * relative to the target window. */
3238static INLINE int
3239xd3_emit_run (xd3_stream *stream, usize_t pos, usize_t size, uint8_t run_c)
3240{
3241 xd3_rinst* ri;
3242 int ret;
3243
3244 XD3_ASSERT (pos + size <= stream->avail_in);
3245
3246 if ((ret = xd3_iopt_get_slot (stream, & ri))) { return ret; }
3247
3248 ri->type = XD3_RUN;
3249 ri->xtra = run_c;
3250 ri->pos = pos;
3251 ri->size = size;
3252
3253 return 0;
3254}
3255
3256/* This enters a potential copy instruction into the iopt buffer. The position argument
3257 * is relative to the target window.. */
3258static INLINE int
3259xd3_found_match (xd3_stream *stream, usize_t pos, usize_t size, xoff_t addr, int is_source)
3260{
3261 xd3_rinst* ri;
3262 int ret;
3263
3264 XD3_ASSERT (pos + size <= stream->avail_in);
3265
3266 if ((ret = xd3_iopt_get_slot (stream, & ri))) { return ret; }
3267
3268 ri->type = XD3_CPY;
3269 ri->xtra = is_source;
3270 ri->pos = pos;
3271 ri->size = size;
3272 ri->addr = addr;
3273
3274 return 0;
3275}
3276
3277static int
3278xd3_emit_hdr (xd3_stream *stream)
3279{
3280 int ret;
3281 int use_secondary = stream->sec_type != NULL;
3282 int use_adler32 = stream->flags & XD3_ADLER32;
3283 int vcd_source = xd3_encoder_used_source (stream);
3284 uint win_ind = 0;
3285 uint del_ind = 0;
3286 usize_t enc_len;
3287 usize_t tgt_len;
3288 usize_t data_len;
3289 usize_t inst_len;
3290 usize_t addr_len;
3291
3292 XD3_ASSERT (stream->n_emit == stream->avail_in);
3293
3294 if (stream->current_window == 0)
3295 {
3296 uint hdr_ind = 0;
3297 int use_appheader = stream->enc_appheader != NULL;
3298 int use_gencodetbl = GENERIC_ENCODE_TABLES && (stream->code_table_desc != & __rfc3284_code_table_desc);
3299
3300 if (use_secondary) { hdr_ind |= VCD_SECONDARY; }
3301 if (use_gencodetbl) { hdr_ind |= VCD_CODETABLE; }
3302 if (use_appheader) { hdr_ind |= VCD_APPHEADER; }
3303
3304 if ((ret = xd3_emit_byte (stream, & HDR_TAIL (stream), VCDIFF_MAGIC1)) != 0 ||
3305 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), VCDIFF_MAGIC2)) != 0 ||
3306 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), VCDIFF_MAGIC3)) != 0 ||
3307 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), VCDIFF_VERSION)) != 0 ||
3308 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), hdr_ind)) != 0)
3309 {
3310 return ret;
3311 }
3312
3313 /* Secondary compressor ID */
3314#if SECONDARY_ANY
3315 if (use_secondary && (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), stream->sec_type->id))) { return ret; }
3316#endif
3317
3318 /* Compressed code table */
3319 if (use_gencodetbl)
3320 {
3321 usize_t code_table_size;
3322 const uint8_t *code_table_data;
3323
3324 if ((ret = stream->comp_table_func (stream, & code_table_data, & code_table_size))) { return ret; }
3325
3326 if ((ret = xd3_emit_size (stream, & HDR_TAIL (stream), code_table_size + 2)) ||
3327 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), stream->code_table_desc->near_modes)) ||
3328 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), stream->code_table_desc->same_modes)) ||
3329 (ret = xd3_emit_bytes (stream, & HDR_TAIL (stream), code_table_data, code_table_size))) { return ret; }
3330 }
3331
3332 /* Application header */
3333 if (use_appheader)
3334 {
3335 if ((ret = xd3_emit_size (stream, & HDR_TAIL (stream), stream->enc_appheadsz)) ||
3336 (ret = xd3_emit_bytes (stream, & HDR_TAIL (stream), stream->enc_appheader, stream->enc_appheadsz)))
3337 {
3338 return ret;
3339 }
3340 }
3341 }
3342
3343 /* try to compress this window */
3344#if SECONDARY_ANY
3345 if (use_secondary)
3346 {
3347 int data_sec = 0;
3348 int inst_sec = 0;
3349 int addr_sec = 0;
3350
3351# define ENCODE_SECONDARY_SECTION(UPPER,LOWER) \
3352 ((stream->flags & XD3_SEC_NO ## UPPER) == 0 && \
3353 (ret = xd3_encode_secondary (stream, & UPPER ## _HEAD (stream), & UPPER ## _TAIL (stream), \
3354 & xd3_sec_ ## LOWER (stream), \
3355 & stream->sec_ ## LOWER, & LOWER ## _sec)))
3356
3357 if (ENCODE_SECONDARY_SECTION (DATA, data) ||
3358 ENCODE_SECONDARY_SECTION (INST, inst) ||
3359 ENCODE_SECONDARY_SECTION (ADDR, addr))
3360 {
3361 return ret;
3362 }
3363
3364 del_ind |= (data_sec ? VCD_DATACOMP : 0);
3365 del_ind |= (inst_sec ? VCD_INSTCOMP : 0);
3366 del_ind |= (addr_sec ? VCD_ADDRCOMP : 0);
3367 }
3368#endif
3369
3370 /* if (vcd_target) { win_ind |= VCD_TARGET; } */
3371 if (vcd_source) { win_ind |= VCD_SOURCE; }
3372 if (use_adler32) { win_ind |= VCD_ADLER32; }
3373
3374 /* window indicator */
3375 if ((ret = xd3_emit_byte (stream, & HDR_TAIL (stream), win_ind))) { return ret; }
3376
3377 /* source window */
3378 if (vcd_source)
3379 {
3380 /* or (vcd_target) { ... } */
3381 if ((ret = xd3_emit_size (stream, & HDR_TAIL (stream), stream->src->srclen)) ||
3382 (ret = xd3_emit_offset (stream, & HDR_TAIL (stream), stream->src->srcbase))) { return ret; }
3383 }
3384
3385 tgt_len = stream->avail_in;
3386 data_len = xd3_sizeof_output (DATA_HEAD (stream));
3387 inst_len = xd3_sizeof_output (INST_HEAD (stream));
3388 addr_len = xd3_sizeof_output (ADDR_HEAD (stream));
3389
3390 /* The enc_len field is redundent... doh! */
3391 enc_len = (1 + (xd3_sizeof_size (tgt_len) +
3392 xd3_sizeof_size (data_len) +
3393 xd3_sizeof_size (inst_len) +
3394 xd3_sizeof_size (addr_len)) +
3395 data_len +
3396 inst_len +
3397 addr_len +
3398 (use_adler32 ? 4 : 0));
3399
3400 if ((ret = xd3_emit_size (stream, & HDR_TAIL (stream), enc_len)) ||
3401 (ret = xd3_emit_size (stream, & HDR_TAIL (stream), tgt_len)) ||
3402 (ret = xd3_emit_byte (stream, & HDR_TAIL (stream), del_ind)) ||
3403 (ret = xd3_emit_size (stream, & HDR_TAIL (stream), data_len)) ||
3404 (ret = xd3_emit_size (stream, & HDR_TAIL (stream), inst_len)) ||
3405 (ret = xd3_emit_size (stream, & HDR_TAIL (stream), addr_len)))
3406 {
3407 return ret;
3408 }
3409
3410 if (use_adler32)
3411 {
3412 uint8_t send[4];
3413 uint32_t a32 = adler32 (1L, stream->next_in, stream->avail_in);
3414
3415 send[0] = (a32 >> 24);
3416 send[1] = (a32 >> 16);
3417 send[2] = (a32 >> 8);
3418 send[3] = (a32 & 0xff);
3419
3420 if ((ret = xd3_emit_bytes (stream, & HDR_TAIL (stream), send, 4))) { return ret; }
3421 }
3422
3423 return 0;
3424}
3425
3426/******************************************************************************************
3427 Encode routines
3428 ******************************************************************************************/
3429
3430static int
3431xd3_encode_buffer_leftover (xd3_stream *stream)
3432{
3433 usize_t take;
3434 usize_t room;
3435
3436 /* Allocate the buffer. */
3437 if (stream->buf_in == NULL && (stream->buf_in = xd3_alloc (stream, stream->winsize, 1)) == NULL)
3438 {
3439 return ENOMEM;
3440 }
3441
3442 /* Take leftover input first. */
3443 if (stream->buf_leftover != NULL)
3444 {
3445 XD3_ASSERT (stream->buf_avail == 0);
3446 XD3_ASSERT (stream->buf_leftavail < stream->winsize);
3447
3448 IF_DEBUG1 (DP(RINT "[leftover] previous %u avail %u\n", stream->buf_leftavail, stream->avail_in));
3449
3450 memcpy (stream->buf_in, stream->buf_leftover, stream->buf_leftavail);
3451
3452 stream->buf_leftover = NULL;
3453 stream->buf_avail = stream->buf_leftavail;
3454 }
3455
3456 /* Copy into the buffer. */
3457 room = stream->winsize - stream->buf_avail;
3458 take = min (room, stream->avail_in);
3459
3460 memcpy (stream->buf_in + stream->buf_avail, stream->next_in, take);
3461
3462 stream->buf_avail += take;
3463
3464 if (take < stream->avail_in)
3465 {
3466 /* Buffer is full */
3467 stream->buf_leftover = stream->next_in + take;
3468 stream->buf_leftavail = stream->avail_in - take;
3469
3470 IF_DEBUG1 (DP(RINT "[leftover] take %u remaining %u\n", take, stream->buf_leftavail));
3471 }
3472 else if ((stream->buf_avail < stream->winsize) && !(stream->flags & XD3_FLUSH))
3473 {
3474 /* Buffer has space */
3475 IF_DEBUG1 (DP(RINT "[leftover] %u emptied\n", take));
3476 return XD3_INPUT;
3477 }
3478
3479 /* Use the buffer: */
3480 stream->next_in = stream->buf_in;
3481 stream->avail_in = stream->buf_avail;
3482 stream->buf_avail = 0;
3483
3484 return 0;
3485}
3486
3487/* Allocates one block of xd3_rlist elements */
3488static int
3489xd3_alloc_iopt (xd3_stream *stream, int elts)
3490{
3491 int i;
3492 xd3_iopt_buflist* last = xd3_alloc (stream, sizeof (xd3_iopt_buflist), 1);
3493
3494 if (last == NULL ||
3495 (last->buffer = xd3_alloc (stream, sizeof (xd3_rinst), elts)) == NULL)
3496 {
3497 return ENOMEM;
3498 }
3499
3500 last->next = stream->iopt_alloc;
3501 stream->iopt_alloc = last;
3502
3503 for (i = 0; i < elts; i += 1)
3504 {
3505 xd3_rlist_push_back (& stream->iopt_free, & last->buffer[i]);
3506 }
3507
3508 return 0;
3509}
3510
3511/* This function allocates all memory initially used by the encoder. */
3512static int
3513xd3_encode_init (xd3_stream *stream)
3514{
3515 int i;
3516 int large_comp = (stream->src != NULL);
3517 int small_comp = ! (stream->flags & XD3_NOCOMPRESS);
3518
3519 /* Memory allocations for checksum tables are delayed until xd3_string_match_init in the
3520 * first call to string_match--that way identical or short inputs require no table
3521 * allocation. */
3522 if (large_comp)
3523 {
3524 usize_t hash_values = (stream->srcwin_maxsz / stream->smatcher.large_step);
3525
3526 xd3_size_hashtable (stream,
3527 hash_values,
3528 & stream->large_hash);
3529 }
3530
3531 if (small_comp)
3532 {
3533 usize_t hash_values = min(stream->winsize, stream->sprevsz);
3534
3535 xd3_size_hashtable (stream,
3536 hash_values,
3537 & stream->small_hash);
3538 }
3539
3540 for (i = 0; i < ENC_SECTS; i += 1)
3541 {
3542 if ((stream->enc_heads[i] =
3543 stream->enc_tails[i] =
3544 xd3_alloc_output (stream, NULL)) == NULL)
3545 {
3546 goto fail;
3547 }
3548 }
3549
3550 /* iopt buffer */
3551 xd3_rlist_init (& stream->iopt_used);
3552 xd3_rlist_init (& stream->iopt_free);
3553
3554 if (xd3_alloc_iopt (stream, stream->iopt_size) != 0) { goto fail; }
3555
3556 XD3_ASSERT (xd3_rlist_length (& stream->iopt_free) == stream->iopt_size);
3557 XD3_ASSERT (xd3_rlist_length (& stream->iopt_used) == 0);
3558
3559 /* address cache, code table */
3560 stream->acache.s_near = stream->code_table_desc->near_modes;
3561 stream->acache.s_same = stream->code_table_desc->same_modes;
3562 stream->code_table = stream->code_table_func ();
3563
3564 return xd3_alloc_cache (stream);
3565
3566 fail:
3567
3568 return ENOMEM;
3569}
3570
3571/* Called after the ENC_POSTOUT state, this puts the output buffers back into separate
3572 * lists and re-initializes some variables. (The output lists were spliced together
3573 * during the ENC_FLUSH state.) */
3574static void
3575xd3_encode_reset (xd3_stream *stream)
3576{
3577 int i;
3578 xd3_output *olist;
3579
3580 IF_DEBUG (stream->n_emit = 0);
3581 stream->avail_in = 0;
3582 stream->small_reset = 1;
3583 stream->i_slots_used = 0;
3584
3585 if (stream->src != NULL)
3586 {
3587 stream->src->srcbase = 0;
3588 stream->src->srclen = 0;
3589 stream->srcwin_decided = 0;
3590 stream->match_minaddr = 0;
3591 stream->match_maxaddr = 0;
3592 stream->taroff = 0;
3593 }
3594
3595 /* Reset output chains. */
3596 olist = stream->enc_heads[0];
3597
3598 for (i = 0; i < ENC_SECTS; i += 1)
3599 {
3600 XD3_ASSERT (olist != NULL);
3601
3602 stream->enc_heads[i] = olist;
3603 stream->enc_tails[i] = olist;
3604 olist = olist->next_page;
3605
3606 stream->enc_heads[i]->next = 0;
3607 stream->enc_heads[i]->next_page = NULL;
3608
3609 stream->enc_tails[i]->next_page = NULL;
3610 stream->enc_tails[i] = stream->enc_heads[i];
3611 }
3612
3613 xd3_freelist_output (stream, olist);
3614}
3615
3616/* The main encoding routine. */
3617int
3618xd3_encode_input (xd3_stream *stream)
3619{
3620 int ret, i;
3621
3622 if (stream->dec_state != 0)
3623 {
3624 stream->msg = "encoder/decoder transition";
3625 return XD3_INTERNAL;
3626 }
3627
3628 switch (stream->enc_state)
3629 {
3630 case ENC_INIT:
3631 /* Only reached on first time through: memory setup. */
3632 if ((ret = xd3_encode_init (stream))) { return ret; }
3633
3634 stream->enc_state = ENC_INPUT;
3635
3636 case ENC_INPUT:
3637
3638 /* If there is no input yet, just return. This checks for next_in == NULL, not
3639 * avail_in == 0 since zero bytes is a valid input. There is an assertion in
3640 * xd3_avail_input() that next_in != NULL for this reason. By returning right away
3641 * we avoid creating an input buffer before the caller has supplied its first data.
3642 * It is possible for xd3_avail_input to be called both before and after the first
3643 * call to xd3_encode_input(). */
3644 if (stream->next_in == NULL)
3645 {
3646 return XD3_INPUT;
3647 }
3648
3649 enc_flush:
3650 /* See if we should buffer the input: either if there is already a leftover buffer,
3651 * or if the input is short of winsize without flush. The label at this point is
3652 * reached by a goto below, when there is leftover input after postout. */
3653 if ((stream->buf_leftover != NULL) ||
3654 (stream->avail_in < stream->winsize && ! (stream->flags & XD3_FLUSH)))
3655 {
3656 if ((ret = xd3_encode_buffer_leftover (stream))) { return ret; }
3657 }
3658
3659 /* Initalize the address cache before each window. */
3660 xd3_init_cache (& stream->acache);
3661
3662 stream->input_position = 0;
3663 stream->min_match = MIN_MATCH;
3664 stream->unencoded_offset = 0;
3665
3666 stream->enc_state = ENC_SEARCH;
3667
3668 IF_DEBUG1 (DP(RINT "[input window:%"Q"u] input bytes %u offset %"Q"u\n",
3669 stream->current_window, stream->avail_in, stream->total_in));
3670
3671 return XD3_WINSTART;
3672
3673 case ENC_SEARCH:
3674
3675 /* Reentrant matching. */
3676 if (stream->src != NULL)
3677 {
3678 switch (stream->match_state)
3679 {
3680 case MATCH_TARGET:
3681 /* Try matching forward at the start of the target. This is entered the
3682 * first time through, to check for a perfect match, and whenever there is a
3683 * source match that extends to the end of the previous window. The
3684 * match_srcpos field is initially zero and later set during
3685 * xd3_source_extend_match. */
3686 if (stream->avail_in > 0)
3687 {
3688 /* This call can't fail because the source window is unrestricted. */
3689 ret = xd3_source_match_setup (stream, stream->match_srcpos);
3690 XD3_ASSERT (ret == 0);
3691 stream->match_state = MATCH_FORWARD;
3692 }
3693 else
3694 {
3695 stream->match_state = MATCH_SEARCHING;
3696 }
3697 XD3_ASSERT (stream->match_fwd == 0);
3698
3699 case MATCH_FORWARD:
3700 case MATCH_BACKWARD:
3701 if (stream->avail_in != 0)
3702 {
3703 if ((ret = xd3_source_extend_match (stream)) != 0)
3704 {
3705 return ret;
3706 }
3707
3708 stream->input_position += stream->match_fwd;
3709 }
3710
3711 case MATCH_SEARCHING:
3712 /* Continue string matching. (It's possible that the initial match
3713 * continued through the entire input, in which case we're still in
3714 * MATCH_FORWARD and should remain so for the next input window.) */
3715 break;
3716 }
3717 }
3718
3719 /* String matching... */
3720 if (stream->avail_in != 0 &&
3721 (ret = stream->smatcher.string_match (stream)))
3722 {
3723 return ret;
3724 }
3725
3726 /* Flush the instrution buffer, then possibly add one more instruction, then emit
3727 * the header. */
3728 stream->enc_state = ENC_FLUSH;
3729 if ((ret = xd3_iopt_flush_instructions (stream, 1)) ||
3730 (ret = xd3_iopt_add_finalize (stream)) ||
3731 (ret = xd3_emit_hdr (stream)))
3732 {
3733 return ret;
3734 }
3735
3736 /* Begin output. */
3737 stream->enc_current = HDR_HEAD (stream);
3738
3739 /* Chain all the outputs together. After doing this, it looks as if there is only
3740 * one section. The other enc_heads are set to NULL to avoid freeing them more than
3741 * once. */
3742 for (i = 1; i < ENC_SECTS; i += 1)
3743 {
3744 stream->enc_tails[i-1]->next_page = stream->enc_heads[i];
3745 stream->enc_heads[i] = NULL;
3746 }
3747
3748 enc_output:
3749
3750 stream->enc_state = ENC_POSTOUT;
3751 stream->next_out = stream->enc_current->base;
3752 stream->avail_out = stream->enc_current->next;
3753 stream->total_out += (xoff_t) stream->avail_out;
3754
3755 /* If there is any output in this buffer, return it, otherwise fall through to
3756 * handle the next buffer or finish the window after all buffers have been
3757 * output. */
3758 if (stream->avail_out > 0)
3759 {
3760 /* This is the only place xd3_encode returns XD3_OUTPUT */
3761 return XD3_OUTPUT;
3762 }
3763
3764 case ENC_POSTOUT:
3765
3766 if (stream->avail_out != 0)
3767 {
3768 stream->msg = "missed call to consume output";
3769 return XD3_INTERNAL;
3770 }
3771
3772 /* Continue outputting one buffer at a time, until the next is NULL. */
3773 if ((stream->enc_current = stream->enc_current->next_page) != NULL)
3774 {
3775 goto enc_output;
3776 }
3777
3778 stream->total_in += (xoff_t) stream->avail_in;
3779 stream->enc_state = ENC_POSTWIN;
3780
3781 return XD3_WINFINISH;
3782
3783 case ENC_POSTWIN:
3784
3785 xd3_encode_reset (stream);
3786
3787 stream->current_window += 1;
3788 stream->enc_state = ENC_INPUT;
3789
3790 /* If there is leftover input to flush, repeat. */
3791 if ((stream->buf_leftover != NULL) && (stream->flags & XD3_FLUSH))
3792 {
3793 goto enc_flush;
3794 }
3795
3796 /* Ready for more input. */
3797 return XD3_INPUT;
3798
3799 default:
3800 stream->msg = "invalid state";
3801 return XD3_INTERNAL;
3802 }
3803}
3804#endif /* XD3_ENCODER */
3805
3806/******************************************************************************************
3807 Client convenience functions
3808 ******************************************************************************************/
3809
3810static int
3811xd3_process_stream (int is_encode,
3812 xd3_stream *stream,
3813 int (*func) (xd3_stream *),
3814 int close_stream,
3815 const uint8_t *input,
3816 usize_t input_size,
3817 uint8_t *output,
3818 usize_t *output_size,
3819 usize_t output_size_max)
3820{
3821 usize_t ipos = 0;
3822 usize_t n = min(stream->winsize, input_size);
3823
3824 (*output_size) = 0;
3825
3826 stream->flags |= XD3_FLUSH;
3827
3828 xd3_avail_input (stream, input + ipos, n);
3829 ipos += n;
3830
3831 for (;;)
3832 {
3833 int ret;
3834 switch((ret = func (stream)))
3835 {
3836 case XD3_OUTPUT: { /* memcpy below */ break; }
3837 case XD3_INPUT: {
3838 n = min(stream->winsize, input_size - ipos);
3839 if (n == 0) {
3840 goto done;
3841 }
3842 xd3_avail_input (stream, input + ipos, n);
3843 ipos += n;
3844 continue;
3845 }
3846 case XD3_GOTHEADER: { /* ignore */ continue; }
3847 case XD3_WINSTART: { /* ignore */ continue; }
3848 case XD3_WINFINISH: { /* ignore */ continue; }
3849 case XD3_GETSRCBLK:
3850 {
3851 stream->msg = "stream requires source input";
3852 return XD3_INTERNAL;
3853 }
3854 case 0:
3855 {
3856 /* xd3_encode_input/xd3_decode_input never return 0 */
3857 stream->msg = "invalid return: 0";
3858 return XD3_INTERNAL;
3859 }
3860 default:
3861 return ret;
3862 }
3863
3864 if (*output_size + stream->avail_out > output_size_max)
3865 {
3866 stream->msg = "insufficient output space";
3867 return ENOSPC;
3868 }
3869
3870 memcpy (output + *output_size, stream->next_out, stream->avail_out);
3871
3872 *output_size += stream->avail_out;
3873
3874 xd3_consume_output (stream);
3875 }
3876 done:
3877 return (close_stream == 0) ? 0 : xd3_close_stream (stream);
3878}
3879
3880static int
3881xd3_process_memory (int is_encode,
3882 int (*func) (xd3_stream *),
3883 int close_stream,
3884 const uint8_t *input,
3885 usize_t input_size,
3886 const uint8_t *source,
3887 usize_t source_size,
3888 uint8_t *output,
3889 usize_t *output_size,
3890 usize_t output_size_max,
3891 int flags) {
3892 xd3_stream stream;
3893 xd3_config config;
3894 xd3_source src;
3895 int ret;
3896
3897 if (input == NULL || output == NULL) {
3898 stream.msg = "invalid input/output buffer";
3899 return XD3_INTERNAL;
3900 }
3901
3902 memset (& stream, 0, sizeof (stream));
3903 memset (& config, 0, sizeof (config));
3904
3905 config.flags = flags;
3906
3907 if (is_encode)
3908 {
3909 config.srcwin_maxsz = source_size;
3910 config.winsize = min(input_size, (usize_t) XD3_DEFAULT_WINSIZE);
3911 config.iopt_size = min(input_size / 32, XD3_DEFAULT_IOPT_SIZE);
3912 config.iopt_size = max(config.iopt_size, 128U);
3913
3914 config.sprevsz = XD3_DEFAULT_SPREVSZ;
3915
3916 while (config.sprevsz / 2 > input_size)
3917 {
3918 config.sprevsz /= 2;
3919 }
3920 }
3921
3922 if ((ret = xd3_config_stream (&stream, &config)) != 0)
3923 {
3924 goto exit;
3925 }
3926
3927 if (source != NULL)
3928 {
3929 memset (& src, 0, sizeof (src));
3930 src.size = source_size;
3931 src.blksize = source_size;
3932 src.onblk = source_size;
3933 src.curblk = source;
3934 src.curblkno = 0;
3935
3936 if ((ret = xd3_set_source (&stream, &src)) != 0)
3937 {
3938 goto exit;
3939 }
3940 }
3941
3942 if ((ret = xd3_process_stream (is_encode,
3943 & stream,
3944 func, 1,
3945 input, input_size,
3946 output,
3947 output_size,
3948 output_size_max)) != 0)
3949 {
3950 goto exit;
3951 }
3952
3953 exit:
3954 xd3_free_stream(&stream);
3955 return ret;
3956}
3957
3958int
3959xd3_decode_stream (xd3_stream *stream,
3960 const uint8_t *input,
3961 usize_t input_size,
3962 uint8_t *output,
3963 usize_t *output_size,
3964 usize_t output_size_max)
3965{
3966 return xd3_process_stream (0, stream, & xd3_decode_input, 1,
3967 input, input_size,
3968 output, output_size, output_size_max);
3969}
3970
3971int
3972xd3_decode_memory (const uint8_t *input,
3973 usize_t input_size,
3974 const uint8_t *source,
3975 usize_t source_size,
3976 uint8_t *output,
3977 usize_t *output_size,
3978 usize_t output_size_max,
3979 int flags) {
3980 return xd3_process_memory (0, & xd3_decode_input, 1,
3981 input, input_size,
3982 source, source_size,
3983 output, output_size, output_size_max,
3984 flags);
3985}
3986
3987
3988#if XD3_ENCODER
3989int
3990xd3_encode_stream (xd3_stream *stream,
3991 const uint8_t *input,
3992 usize_t input_size,
3993 uint8_t *output,
3994 usize_t *output_size,
3995 usize_t output_size_max)
3996{
3997 return xd3_process_stream (1, stream, & xd3_encode_input, 1,
3998 input, input_size,
3999 output, output_size, output_size_max);
4000}
4001
4002int
4003xd3_encode_memory (const uint8_t *input,
4004 usize_t input_size,
4005 const uint8_t *source,
4006 usize_t source_size,
4007 uint8_t *output,
4008 usize_t *output_size,
4009 usize_t output_size_max,
4010 int flags) {
4011 return xd3_process_memory (1, & xd3_encode_input, 1,
4012 input, input_size,
4013 source, source_size,
4014 output, output_size, output_size_max,
4015 flags);
4016}
4017#endif
4018
4019
4020/******************************************************************************************
4021 String matching helpers
4022 ******************************************************************************************/
4023
4024#if XD3_ENCODER
4025/* Do the initial xd3_string_match() checksum table setup. Allocations are delayed until
4026 * first use to avoid allocation sometimes (e.g., perfect matches, zero-length inputs). */
4027static int
4028xd3_string_match_init (xd3_stream *stream)
4029{
4030 const int DO_SMALL = ! (stream->flags & XD3_NOCOMPRESS);
4031 const int DO_LARGE = (stream->src != NULL);
4032
4033 if (DO_LARGE && stream->large_table == NULL)
4034 {
4035 if ((stream->large_table = xd3_alloc0 (stream, stream->large_hash.size, sizeof (usize_t))) == NULL)
4036 {
4037 return ENOMEM;
4038 }
4039 }
4040
4041 if (DO_SMALL)
4042 {
4043 /* Subsequent calls can return immediately after checking reset. */
4044 if (stream->small_table != NULL)
4045 {
4046 /* The target hash table is reinitialized once per window. */
4047 /* TODO: This would not have to be reinitialized if absolute offsets
4048 * were being stored, as we would do for VCD_TARGET encoding. */
4049 if (stream->small_reset)
4050 {
4051 stream->small_reset = 0;
4052 memset (stream->small_table, 0, sizeof (usize_t) * stream->small_hash.size);
4053 }
4054
4055 return 0;
4056 }
4057
4058 if ((stream->small_table = xd3_alloc0 (stream,
4059 stream->small_hash.size,
4060 sizeof (usize_t))) == NULL)
4061 {
4062 return ENOMEM;
4063 }
4064
4065 /* If there is a previous table needed. */
4066 if (stream->smatcher.small_lchain > 1 ||
4067 stream->smatcher.small_chain > 1)
4068 {
4069 if ((stream->small_prev = xd3_alloc (stream,
4070 stream->sprevsz,
4071 sizeof (xd3_slist))) == NULL)
4072 {
4073 return ENOMEM;
4074 }
4075 }
4076 }
4077
4078 return 0;
4079}
4080
4081#if XD3_USE_LARGEFILE64
4082/* This function handles the 32/64bit ambiguity -- file positions are 64bit but the hash
4083 * table for source-offsets is 32bit. */
4084static xoff_t
4085xd3_source_cksum_offset(xd3_stream *stream, usize_t low)
4086{
4087 xoff_t scp = stream->srcwin_cksum_pos;
4088 xoff_t s0 = scp >> 32;
4089
4090 usize_t sr = (usize_t) scp;
4091
4092 if (s0 == 0) {
4093 return low;
4094 }
4095
4096 /* This should not be >= because srcwin_cksum_pos is the next
4097 * position to index. */
4098 if (low > sr) {
4099 return (--s0 << 32) | low;
4100 }
4101
4102 return (s0 << 32) | low;
4103}
4104#else
4105static xoff_t
4106xd3_source_cksum_offset(xd3_stream *stream, usize_t low)
4107{
4108 return (xoff_t) low;
4109}
4110#endif
4111
4112/* This function sets up the stream->src fields srcbase, srclen. The call is delayed
4113 * until these values are needed to encode a copy address. At this point the decision has
4114 * to be made. */
4115static int
4116xd3_srcwin_setup (xd3_stream *stream)
4117{
4118 xd3_source *src = stream->src;
4119 xoff_t length;
4120
4121 /* Check the undecided state. */
4122 XD3_ASSERT (src->srclen == 0 && src->srcbase == 0);
4123
4124 /* Avoid repeating this call. */
4125 stream->srcwin_decided = 1;
4126
4127 /* If the stream is flushing, then the iopt buffer was able to contain the complete
4128 * encoding. If no copies were issued no source window is actually needed. This
4129 * prevents the VCDIFF header from including source base/len. xd3_emit_hdr checks
4130 * for srclen == 0. */
4131 if (stream->enc_state == ENC_FLUSH && stream->match_maxaddr == 0)
4132 {
4133 goto done;
4134 }
4135
4136 /* Check for overflow, srclen is usize_t - this can't happen unless XD3_DEFAULT_SRCBACK
4137 * and related parameters are extreme - should use smaller windows. */
4138 length = stream->match_maxaddr - stream->match_minaddr;
4139
4140 if (length > (xoff_t) USIZE_T_MAX)
4141 {
4142 stream->msg = "source window length overflow (not 64bit)";
4143 return XD3_INTERNAL;
4144 }
4145
4146 /* If ENC_FLUSH, then we know the exact source window to use because no more copies can
4147 * be issued. */
4148 if (stream->enc_state == ENC_FLUSH)
4149 {
4150 src->srcbase = stream->match_minaddr;
4151 src->srclen = (usize_t) length;
4152 XD3_ASSERT (src->srclen);
4153 goto done;
4154 }
4155
4156 /* Otherwise, we have to make a guess. More copies may still be issued, but we have to
4157 * decide the source window base and length now. */
4158 src->srcbase = stream->match_minaddr;
4159 src->srclen = max ((usize_t) length, stream->avail_in + (stream->avail_in >> 2));
4160 if (src->size < src->srcbase + (xoff_t) src->srclen)
4161 {
4162 /* Could reduce srcbase, as well. */
4163 src->srclen = src->size - src->srcbase;
4164 }
4165
4166 XD3_ASSERT (src->srclen);
4167 done:
4168 /* Set the taroff. This convenience variable is used even when stream->src == NULL. */
4169 stream->taroff = src->srclen;
4170 return 0;
4171}
4172
4173/* This function computes more source checksums to advance the window.
4174 * Called at every entrance to the string-match loop and each time
4175 * stream->input_position reaches the value returned as
4176 * *next_move_point. NB: this is one of the most expensive functions
4177 * in this code and also the most critical for good compression.
4178 *
4179 * TODO: really would like a good test for this logic. how?
4180 * TODO: optimize the inner loop
4181 */
4182static int
4183xd3_srcwin_move_point (xd3_stream *stream, usize_t *next_move_point)
4184{
4185 xoff_t logical_input_cksum_pos;
4186
4187 XD3_ASSERT(stream->srcwin_cksum_pos <= stream->src->size);
4188 if (stream->srcwin_cksum_pos == stream->src->size)
4189 {
4190 *next_move_point = USIZE_T_MAX;
4191 return 0;
4192 }
4193
4194 /* Begin by advancing at twice the input rate, up to half the
4195 * maximum window size. */
4196 logical_input_cksum_pos = min((stream->total_in + stream->input_position) * 2,
4197 (stream->total_in + stream->input_position) +
4198 (stream->srcwin_maxsz / 2));
4199
4200 /* If srcwin_cksum_pos is already greater, wait until the difference
4201 * is met. */
4202 if (stream->srcwin_cksum_pos > logical_input_cksum_pos)
4203 {
4204 *next_move_point = stream->input_position +
4205 (usize_t)(stream->srcwin_cksum_pos - logical_input_cksum_pos);
4206 return 0;
4207 }
4208
4209 /* A long match may have extended past srcwin_cksum_pos. Don't
4210 * start checksumming already-matched source data. */
4211 if (stream->maxsrcaddr > stream->srcwin_cksum_pos)
4212 {
4213 stream->srcwin_cksum_pos = stream->maxsrcaddr;
4214 }
4215
4216 if (logical_input_cksum_pos < stream->srcwin_cksum_pos)
4217 {
4218 logical_input_cksum_pos = stream->srcwin_cksum_pos;
4219 }
4220
4221 /* Advance at least one source block. With the command-line
4222 * defaults this means:
4223 *
4224 * if (src->size <= srcwin_maxsz), index the entire source at once
4225 * using the position of the first non-match. This is good for
4226 * small inputs, especially when the content may have moved anywhere
4227 * in the file (e.g., tar files).
4228 *
4229 * if (src->size > srcwin_maxsz), index at least one block (which
4230 * the command-line sets to 1/32 of srcwin_maxsz) ahead of the
4231 * logical position. This is good for different reasons: when a
4232 * long match spanning several source blocks is encountered, this
4233 * avoids computing checksums for those blocks. If the data can
4234 * move anywhere, this is bad.
4235 */
4236 logical_input_cksum_pos += stream->src->blksize;
4237
4238 IF_DEBUG1 (DP(RINT "[srcwin_move_point] T=%"Q"u S=%"Q"u/%"Q"u\n",
4239 stream->total_in + stream->input_position,
4240 stream->srcwin_cksum_pos,
4241 logical_input_cksum_pos));
4242
4243 while (stream->srcwin_cksum_pos < logical_input_cksum_pos &&
4244 stream->srcwin_cksum_pos < stream->src->size)
4245 {
4246 xoff_t blkno = stream->srcwin_cksum_pos / stream->src->blksize;
4247 ssize_t oldpos = stream->srcwin_cksum_pos % stream->src->blksize;
4248 ssize_t blkpos = xd3_bytes_on_srcblk (stream->src, blkno);
4249 int ret;
4250
4251 if (oldpos + stream->smatcher.large_look > blkpos)
4252 {
4253 stream->srcwin_cksum_pos = (blkno + 1) * stream->src->blksize;
4254 continue;
4255 }
4256
4257 if ((ret = xd3_getblk (stream, blkno)))
4258 {
4259 /* TOOFARBACK should never occur here, since we read forward. */
4260 if (ret == XD3_TOOFARBACK)
4261 {
4262 ret = XD3_INTERNAL;
4263 }
4264 return ret;
4265 }
4266
4267 /* This inserts checksums for the entire block, in reverse,
4268 * starting from the end of the block. This logic does not test
4269 * stream->srcwin_cksum_pos because it always advances it to the
4270 * start of the next block.
4271 *
4272 * oldpos is the srcwin_cksum_pos within this block. blkpos is
4273 * the number of bytes available. Each iteration inspects
4274 * large_look bytes then steps back large_step bytes. The
4275 * if-stmt above ensures at least one large_look of data. */
4276 blkpos -= stream->smatcher.large_look;
4277
4278 do
4279 {
4280 uint32_t cksum = xd3_lcksum (stream->src->curblk + blkpos,
4281 stream->smatcher.large_look);
4282 usize_t hval = xd3_checksum_hash (& stream->large_hash, cksum);
4283
4284 stream->large_table[hval] =
4285 (usize_t) ((stream->src->blksize * blkno) +
4286 (xoff_t)(blkpos + HASH_CKOFFSET));
4287
4288 IF_DEBUG (stream->large_ckcnt += 1);
4289
4290 blkpos -= stream->smatcher.large_step;
4291 }
4292 while (blkpos >= oldpos);
4293
4294 stream->srcwin_cksum_pos = (blkno + 1) * stream->src->blksize;
4295 }
4296
4297 if (stream->srcwin_cksum_pos >= stream->src->size)
4298 {
4299 /* This invariant is needed for xd3_source_cksum_offset() */
4300 stream->srcwin_cksum_pos = stream->src->size;
4301 *next_move_point = USIZE_T_MAX;
4302 return 0;
4303 }
4304
4305 /* How long until this function should be called again. */
4306 XD3_ASSERT(stream->srcwin_cksum_pos >= logical_input_cksum_pos);
4307 *next_move_point = stream->input_position + 1 +
4308 (usize_t)(stream->srcwin_cksum_pos - logical_input_cksum_pos);
4309 return 0;
4310}
4311
4312/* Sets the bounding region for a newly discovered source match, prior to calling
4313 * xd3_source_extend_match(). This sets the match_maxfwd, match_maxback variables. Note:
4314 * srcpos is an absolute position (xoff_t) but the match_maxfwd, match_maxback variables
4315 * are usize_t. Returns 0 if the setup succeeds, or 1 if the source position lies outside
4316 * an already-decided srcbase/srclen window. */
4317static int
4318xd3_source_match_setup (xd3_stream *stream, xoff_t srcpos)
4319{
4320 xd3_source *src = stream->src;
4321 usize_t greedy_or_not;
4322
4323 stream->match_maxback = 0;
4324 stream->match_maxfwd = 0;
4325 stream->match_back = 0;
4326 stream->match_fwd = 0;
4327
4328 /* Going backwards, the 1.5-pass algorithm allows some already-matched input may be
4329 * covered by a longer source match. The greedy algorithm does not allow this. */
4330 if (stream->flags & XD3_BEGREEDY)
4331 {
4332 /* The greedy algorithm allows backward matching to the last matched position. */
4333 greedy_or_not = xd3_iopt_last_matched (stream);
4334 }
4335 else
4336 {
4337 /* The 1.5-pass algorithm allows backward matching to go back as far as the
4338 * unencoded offset, which is updated as instructions pass out of the iopt buffer.
4339 * If this (default) is chosen, it means xd3_iopt_erase may be called to eliminate
4340 * instructions when a covering source match is found. */
4341 greedy_or_not = stream->unencoded_offset;
4342 }
4343
4344
4345
4346 /* Backward target match limit. */
4347 XD3_ASSERT (stream->input_position >= greedy_or_not);
4348 stream->match_maxback = stream->input_position - greedy_or_not;
4349
4350 /* Forward target match limit. */
4351 XD3_ASSERT (stream->avail_in > stream->input_position);
4352 stream->match_maxfwd = stream->avail_in - stream->input_position;
4353
4354 /* Now we take the source position into account. It depends whether the srclen/srcbase
4355 * have been decided yet. */
4356 if (stream->srcwin_decided == 0)
4357 {
4358 /* Unrestricted case: the match can cover the entire source, 0--src->size. We
4359 * compare the usize_t match_maxfwd/match_maxback against the xoff_t src->size/srcpos values
4360 * and take the min. */
4361 xoff_t srcavail;
4362
4363 if (srcpos < (xoff_t) stream->match_maxback)
4364 {
4365 stream->match_maxback = srcpos;
4366 }
4367
4368 srcavail = src->size - srcpos;
4369 if (srcavail < (xoff_t) stream->match_maxfwd)
4370 {
4371 stream->match_maxfwd = srcavail;
4372 }
4373
4374 goto good;
4375 }
4376
4377 /* Decided some source window. */
4378 XD3_ASSERT (src->srclen > 0);
4379
4380 /* Restricted case: fail if the srcpos lies outside the source window */
4381 if ((srcpos < src->srcbase) || (srcpos > (src->srcbase + (xoff_t) src->srclen)))
4382 {
4383 goto bad;
4384 }
4385 else
4386 {
4387 usize_t srcavail;
4388
4389 srcavail = (usize_t) (srcpos - src->srcbase);
4390 if (srcavail < stream->match_maxback)
4391 {
4392 stream->match_maxback = srcavail;
4393 }
4394
4395 srcavail = (usize_t) (src->srcbase + (xoff_t) src->srclen - srcpos);
4396 if (srcavail < stream->match_maxfwd) {
4397 stream->match_maxfwd = srcavail;
4398 }
4399
4400 goto good;
4401 }
4402
4403 good:
4404 stream->match_state = MATCH_BACKWARD;
4405 stream->match_srcpos = srcpos;
4406 return 0;
4407
4408 bad:
4409 stream->match_state = MATCH_SEARCHING;
4410 return 1;
4411}
4412
4413/* This function expands the source match backward and forward. It is reentrant, since
4414 * xd3_getblk may return XD3_GETSRCBLK, so most variables are kept in xd3_stream. There
4415 * are two callers of this function, the string_matching routine when a checksum match is
4416 * discovered, and xd3_encode_input whenever a continuing (or initial) match is suspected.
4417 * The two callers do different things with the input_position, thus this function leaves
4418 * that variable untouched. If a match is taken the resulting stream->match_fwd is left
4419 * non-zero. */
4420static int
4421xd3_source_extend_match (xd3_stream *stream)
4422{
4423 int ret;
4424 xd3_source *src = stream->src;
4425 xoff_t matchoff; /* matchoff is the current right/left-boundary of the source match being tested. */
4426 usize_t streamoff; /* streamoff is the current right/left-boundary of the input match being tested. */
4427 xoff_t tryblk; /* tryblk, tryoff are the block, offset position of matchoff */
4428 usize_t tryoff;
4429 usize_t tryrem; /* tryrem is the number of matchable bytes on the source block */
4430
4431 XD3_ASSERT (src != NULL);
4432
4433 /* Does it make sense to compute backward match AFTER forward match? */
4434 if (stream->match_state == MATCH_BACKWARD)
4435 {
4436 /* Note: this code is practically duplicated below, substituting
4437 * match_fwd/match_back and direction. Consolidate? */
4438 matchoff = stream->match_srcpos - stream->match_back;
4439 streamoff = stream->input_position - stream->match_back;
4440 tryblk = matchoff / src->blksize;
4441 tryoff = matchoff % src->blksize;
4442
4443 /* this loops backward over source blocks */
4444 while (stream->match_back < stream->match_maxback)
4445 {
4446 /* see if we're backing across a source block boundary */
4447 if (tryoff == 0)
4448 {
4449 tryoff = src->blksize;
4450 tryblk -= 1;
4451 }
4452
4453 if ((ret = xd3_getblk (stream, tryblk)))
4454 {
4455 /* if search went too far back, continue forward. */
4456 if (ret == XD3_TOOFARBACK)
4457 {
4458 break;
4459 }
4460
4461 /* could be a XD3_GETSRCBLK failure. */
4462 return ret;
4463 }
4464
4465 /* OPT: This code can be optimized. */
4466 for (tryrem = min (tryoff, stream->match_maxback - stream->match_back);
4467 tryrem != 0;
4468 tryrem -= 1, stream->match_back += 1)
4469 {
4470 if (src->curblk[tryoff-1] != stream->next_in[streamoff-1])
4471 {
4472 goto doneback;
4473 }
4474
4475 tryoff -= 1;
4476 streamoff -= 1;
4477 }
4478 }
4479
4480 doneback:
4481 stream->match_state = MATCH_FORWARD;
4482 }
4483
4484 XD3_ASSERT (stream->match_state == MATCH_FORWARD);
4485
4486 matchoff = stream->match_srcpos + stream->match_fwd;
4487 streamoff = stream->input_position + stream->match_fwd;
4488 tryblk = matchoff / src->blksize;
4489 tryoff = matchoff % src->blksize;
4490
4491 /* Note: practically the same code as backwards case above: same comments */
4492 while (stream->match_fwd < stream->match_maxfwd)
4493 {
4494 if ((ret = xd3_getblk (stream, tryblk)))
4495 {
4496 /* if search went too far back, continue forward. */
4497 if (ret == XD3_TOOFARBACK)
4498 {
4499 break;
4500 }
4501
4502 /* could be a XD3_GETSRCBLK failure. */
4503 return ret;
4504 }
4505
4506 /* There's a good speedup for doing word comparions: see zlib. */
4507 for (tryrem = min(stream->match_maxfwd - stream->match_fwd,
4508 src->blksize - tryoff);
4509 tryrem != 0;
4510 tryrem -= 1, stream->match_fwd += 1)
4511 {
4512 if (src->curblk[tryoff] != stream->next_in[streamoff])
4513 {
4514 goto donefwd;
4515 }
4516
4517 tryoff += 1;
4518 streamoff += 1;
4519 }
4520
4521 if (tryoff == src->blksize)
4522 {
4523 tryoff = 0;
4524 tryblk += 1;
4525 }
4526 }
4527
4528 donefwd:
4529 stream->match_state = MATCH_SEARCHING;
4530
4531 /* Now decide whether to take the match. There are several ways to answer this
4532 * question and this is likely the best answer. There is currently an assertion
4533 * in xd3_iopt_erase that checks whether min_match works. This variable maintains
4534 * that every match exceeds the end of the previous match. However, it is
4535 * possible that match_back allows us to find a match that goes a long way back
4536 * but not enough forward. We could try an alternate approach, which might help
4537 * or it might just be extra complexity: eliminate the next match_fwd >= min_match
4538 * test and call xd3_iopt_erase right away. Erase instructions as far as it goes
4539 * back, then either remember what was deleted and re-insert it, or count on the
4540 * string-matching algorithm to find that match again. I think it is more
4541 * worthwhile to implement large_hash duplicates. */
4542 if (stream->match_fwd < stream->min_match)
4543 {
4544 stream->match_fwd = 0;
4545 }
4546 else
4547 {
4548 usize_t total = stream->match_fwd + stream->match_back;
4549
4550 /* Correct the variables to remove match_back from the equation. */
4551 usize_t target_position = stream->input_position - stream->match_back;
4552 usize_t match_length = stream->match_back + stream->match_fwd;
4553 xoff_t match_position = stream->match_srcpos - stream->match_back;
4554 xoff_t match_end = stream->match_srcpos + stream->match_fwd;
4555
4556 /* At this point we may have to erase any iopt-buffer instructions that are
4557 * fully covered by a backward-extending copy. */
4558 if (stream->match_back > 0)
4559 {
4560 xd3_iopt_erase (stream, target_position, total);
4561 }
4562
4563 stream->match_back = 0;
4564
4565 /* Update ranges. The first source match occurs with both values set to 0. */
4566 if (stream->match_maxaddr == 0 ||
4567 match_position < stream->match_minaddr)
4568 {
4569 stream->match_minaddr = match_position;
4570 }
4571
4572 if (match_end > stream->match_maxaddr)
4573 {
4574 /* Note: per-window */
4575 stream->match_maxaddr = match_end;
4576 }
4577
4578 if (match_end > stream->maxsrcaddr)
4579 {
4580 /* Note: across windows */
4581 stream->maxsrcaddr = match_end;
4582 }
4583
4584 IF_DEBUG1 ({
4585 static int x = 0;
4586 DP(RINT "[source match:%d] <inp %"Q"u %"Q"u> <src %"Q"u %"Q"u> (%s) [ %u bytes ]\n",
4587 x++,
4588 stream->total_in + target_position,
4589 stream->total_in + target_position + match_length,
4590 match_position,
4591 match_position + match_length,
4592 (stream->total_in + target_position == match_position) ? "same" : "diff",
4593 match_length);
4594 });
4595
4596 if ((ret = xd3_found_match (stream,
4597 /* decoder position */ target_position,
4598 /* length */ match_length,
4599 /* address */ match_position,
4600 /* is_source */ 1)))
4601 {
4602 return ret;
4603 }
4604
4605 /* If the match ends with the available input: */
4606 if (target_position + match_length == stream->avail_in)
4607 {
4608 /* Setup continuing match for the next window. */
4609 stream->match_state = MATCH_TARGET;
4610 stream->match_srcpos = match_end;
4611 }
4612 }
4613
4614 return 0;
4615}
4616
4617/* Update the small hash. Values in the small_table are offset by
4618 * HASH_CKOFFSET (1) to distinguish empty buckets from real offsets. */
4619static void
4620xd3_scksum_insert (xd3_stream *stream,
4621 usize_t inx,
4622 usize_t scksum,
4623 usize_t pos)
4624{
4625 /* If we are maintaining previous duplicates. */
4626 if (stream->small_prev)
4627 {
4628 usize_t last_pos = stream->small_table[inx];
4629 xd3_slist *pos_list = & stream->small_prev[pos & stream->sprevmask];
4630
4631 /* Note last_pos is offset by HASH_CKOFFSET. */
4632 pos_list->last_pos = last_pos;
4633 }
4634
4635 /* Enter the new position into the hash bucket. */
4636 stream->small_table[inx] = pos + HASH_CKOFFSET;
4637}
4638
4639#if XD3_DEBUG
4640static int
4641xd3_check_smatch (const uint8_t *ref0, const uint8_t *inp0,
4642 const uint8_t *inp_max, usize_t cmp_len)
4643{
4644 int i;
4645
4646 for (i = 0; i < cmp_len; i += 1)
4647 {
4648 XD3_ASSERT (ref0[i] == inp0[i]);
4649 }
4650
4651 if (inp0 + cmp_len < inp_max)
4652 {
4653 XD3_ASSERT (inp0[i] != ref0[i]);
4654 }
4655
4656 return 1;
4657}
4658#endif /* XD3_DEBUG */
4659
4660/* When the hash table indicates a possible small string match, it
4661 * calls this routine to find the best match. The first matching
4662 * position is taken from the small_table, HASH_CKOFFSET is subtracted
4663 * to get the actual position. After checking that match, if previous
4664 * linked lists are in use (because stream->smatcher.small_chain > 1),
4665 * previous matches are tested searching for the longest match. If
4666 * (stream->min_match > MIN_MATCH) then a lazy match is in effect.
4667 *
4668 * TODO: This is the second most-expensive function, after
4669 * xd3_srcwin_move_point().
4670 */
4671static usize_t
4672xd3_smatch (xd3_stream *stream,
4673 usize_t base,
4674 usize_t scksum,
4675 usize_t *match_offset)
4676{
4677 usize_t cmp_len;
4678 usize_t match_length = 0;
4679 usize_t chain = (stream->min_match == MIN_MATCH ?
4680 stream->smatcher.small_chain :
4681 stream->smatcher.small_lchain);
4682 const uint8_t *inp_max = stream->next_in + stream->avail_in;
4683 const uint8_t *inp;
4684 const uint8_t *ref;
4685
4686 SMALL_HASH_DEBUG1 (stream, stream->next_in + stream->input_position);
4687
4688 XD3_ASSERT (stream->min_match + stream->input_position <= stream->avail_in);
4689
4690 base -= HASH_CKOFFSET;
4691
4692 again:
4693
4694 /* For small matches, we can always go to the end-of-input because
4695 * the matching position must be less than the input position. */
4696 XD3_ASSERT (base < stream->input_position);
4697
4698 ref = stream->next_in + base;
4699 inp = stream->next_in + stream->input_position;
4700
4701 SMALL_HASH_DEBUG2 (stream, ref);
4702
4703 /* Expand potential match forward. */
4704 while (inp < inp_max && *inp == *ref)
4705 {
4706 ++inp;
4707 ++ref;
4708 }
4709
4710 cmp_len = inp - (stream->next_in + stream->input_position);
4711
4712 /* Verify correctness */
4713 XD3_ASSERT (xd3_check_smatch (stream->next_in + base,
4714 stream->next_in + stream->input_position,
4715 inp_max, cmp_len));
4716
4717 /* Update longest match */
4718 if (cmp_len > match_length)
4719 {
4720 ( match_length) = cmp_len;
4721 (*match_offset) = base;
4722
4723 /* Stop if we match the entire input or have a long_enough match. */
4724 if (inp == inp_max || cmp_len >= stream->smatcher.long_enough)
4725 {
4726 goto done;
4727 }
4728 }
4729
4730 /* If we have not reached the chain limit, see if there is another
4731 previous position. */
4732 while (--chain != 0)
4733 {
4734 /* Calculate the previous offset. */
4735 usize_t last_pos = stream->small_prev[base & stream->sprevmask].last_pos;
4736
4737 if (last_pos == 0)
4738 {
4739 break;
4740 }
4741
4742 last_pos -= HASH_CKOFFSET;
4743 base = last_pos;
4744
4745 /* Stop if the position is wrong (because the lists are not
4746 * re-initialized across input windows). */
4747 if (base < stream->input_position)
4748 {
4749 goto again;
4750 }
4751
4752 break;
4753 }
4754
4755 done:
4756 return match_length;
4757}
4758
4759#if XD3_DEBUG
4760static void
4761xd3_verify_small_state (xd3_stream *stream,
4762 const uint8_t *inp,
4763 uint32_t x_cksum)
4764{
4765 uint32_t cksum = xd3_scksum (inp, stream->smatcher.small_look);
4766
4767 XD3_ASSERT (cksum == x_cksum);
4768}
4769
4770static void
4771xd3_verify_large_state (xd3_stream *stream,
4772 const uint8_t *inp,
4773 uint32_t x_cksum)
4774{
4775 uint32_t cksum = xd3_lcksum (inp, stream->smatcher.large_look);
4776
4777 XD3_ASSERT (cksum == x_cksum);
4778}
4779
4780static void
4781xd3_verify_run_state (xd3_stream *stream,
4782 const uint8_t *inp,
4783 int x_run_l,
4784 uint8_t x_run_c)
4785{
4786 int slook = stream->smatcher.small_look;
4787 uint8_t run_c;
4788 int run_l = xd3_comprun (inp, slook, &run_c);
4789
4790 XD3_ASSERT (run_l == 0 || run_c == x_run_c);
4791 XD3_ASSERT (x_run_l > slook || run_l == x_run_l);
4792}
4793#endif /* XD3_DEBUG */
4794#endif /* XD3_ENCODER */
4795
4796/******************************************************************************************
4797 TEMPLATE pass
4798 ******************************************************************************************/
4799
4800#endif /* __XDELTA3_C_INLINE_PASS__ */
4801#ifdef __XDELTA3_C_TEMPLATE_PASS__
4802
4803#if XD3_ENCODER
4804
4805/******************************************************************************************
4806 Templates
4807 ******************************************************************************************/
4808
4809/* Template macros */
4810#define XD3_TEMPLATE(x) XD3_TEMPLATE2(x,TEMPLATE)
4811#define XD3_TEMPLATE2(x,n) XD3_TEMPLATE3(x,n)
4812#define XD3_TEMPLATE3(x,n) x ## n
4813#define XD3_STRINGIFY(x) XD3_STRINGIFY2(x)
4814#define XD3_STRINGIFY2(x) #x
4815
4816static int XD3_TEMPLATE(xd3_string_match_) (xd3_stream *stream);
4817
4818static const xd3_smatcher XD3_TEMPLATE(__smatcher_) =
4819{
4820 XD3_STRINGIFY(TEMPLATE),
4821 XD3_TEMPLATE(xd3_string_match_),
4822#if SOFTCFG == 1
4823 0, 0, 0, 0, 0, 0, 0
4824#else
4825 LLOOK, LSTEP, SLOOK, SCHAIN, SLCHAIN, MAXLAZY, LONGENOUGH
4826#endif
4827};
4828
4829static int
4830XD3_TEMPLATE(xd3_string_match_) (xd3_stream *stream)
4831{
4832 /* TODO config: These next three variables should be statically compliled in various
4833 * scan_cfg configurations? */
4834 const int DO_SMALL = ! (stream->flags & XD3_NOCOMPRESS);
4835 const int DO_LARGE = (stream->src != NULL);
4836 const int DO_RUN = (1);
4837
4838 const uint8_t *inp;
4839 uint32_t scksum = 0;
4840 uint32_t lcksum = 0;
4841 usize_t sinx;
4842 usize_t linx;
4843 uint8_t run_c;
4844 int run_l;
4845 int ret;
4846 usize_t match_length;
4847 usize_t match_offset; /* "may be unused" warnings are bogus (due to min_match test) */
4848 usize_t next_move_point;
4849
4850 /* If there will be no compression due to settings or short input, skip it entirely. */
4851 if (! (DO_SMALL || DO_LARGE || DO_RUN) ||
4852 stream->input_position + SLOOK > stream->avail_in) { goto loopnomore; }
4853
4854 if ((ret = xd3_string_match_init (stream))) { return ret; }
4855
4856 /* The restartloop label is reached when the incremental loop state needs to be
4857 * reset. */
4858 restartloop:
4859
4860 /* If there is not enough input remaining for any kind of match, skip it. */
4861 if (stream->input_position + SLOOK > stream->avail_in) { goto loopnomore; }
4862
4863 /* Now reset the incremental loop state: */
4864
4865 /* The min_match variable is updated to avoid matching the same lazy match over and over
4866 * again. For example, if you find a (small) match of length 9 at one position, you
4867 * will likely find a match of length 8 at the next position. */
4868 stream->min_match = MIN_MATCH;
4869
4870 /* The current input byte. */
4871 inp = stream->next_in + stream->input_position;
4872
4873 /* Small match state. */
4874 if (DO_SMALL)
4875 {
4876 scksum = xd3_scksum (inp, SLOOK);
4877 }
4878
4879 /* Run state. */
4880 if (DO_RUN)
4881 {
4882 run_l = xd3_comprun (inp, SLOOK, & run_c);
4883 }
4884
4885 /* Large match state. We continue the loop even after not enough bytes for LLOOK
4886 * remain, so always check stream->input_position in DO_LARGE code. */
4887 if (DO_LARGE && (stream->input_position + LLOOK <= stream->avail_in))
4888 {
4889 /* Source window: next_move_point is the point that stream->input_position must reach before
4890 * computing more source checksum. */
4891 if ((ret = xd3_srcwin_move_point (stream, & next_move_point)))
4892 {
4893 return ret;
4894 }
4895
4896 lcksum = xd3_lcksum (inp, LLOOK);
4897 }
4898
4899 /* TRYLAZYLEN: True if a certain length match should be followed by lazy search. This
4900 * checks that LEN is shorter than MAXLAZY and that there is enough leftover data to
4901 * consider lazy matching. "Enough" is set to 2 since the next match will start at the
4902 * next offset, it must match two extra characters. */
4903#define TRYLAZYLEN(LEN,POS,MAX) ((MAXLAZY) > 0 && (LEN) < (MAXLAZY) && (POS) + (LEN) <= (MAX) - 2)
4904
4905 /* HANDLELAZY: This statement is called each time an instruciton is emitted (three
4906 * cases). If the instruction is large enough, the loop is restarted, otherwise lazy
4907 * matching may ensue. */
4908#define HANDLELAZY(mlen) \
4909 if (TRYLAZYLEN ((mlen), (stream->input_position), (stream->avail_in))) \
4910 { stream->min_match = (mlen) + LEAST_MATCH_INCR; goto updateone; } \
4911 else \
4912 { stream->input_position += (mlen); goto restartloop; }
4913
4914 /* Now loop over one input byte at a time until a match is found... */
4915 for (;; inp += 1, stream->input_position += 1)
4916 {
4917 /* Now we try three kinds of string match in order of expense:
4918 * run, large match, small match. */
4919
4920 /* Expand the start of a RUN. The test for (run_l == SLOOK) avoids repeating this
4921 * check when we pass through a run area performing lazy matching. The run is only
4922 * expanded once when the min_match is first reached. If lazy matching is
4923 * performed, the run_l variable will remain inconsistent until the first
4924 * non-running input character is reached, at which time the run_l may then again
4925 * grow to SLOOK. */
4926 if (DO_RUN && run_l == SLOOK)
4927 {
4928 usize_t max_len = stream->avail_in - stream->input_position;
4929
4930 IF_DEBUG (xd3_verify_run_state (stream, inp, run_l, run_c));
4931
4932 while (run_l < max_len && inp[run_l] == run_c) { run_l += 1; }
4933
4934 /* Output a RUN instruction. */
4935 if (run_l >= stream->min_match && run_l >= MIN_RUN)
4936 {
4937 if ((ret = xd3_emit_run (stream, stream->input_position, run_l, run_c))) { return ret; }
4938
4939 HANDLELAZY (run_l);
4940 }
4941 }
4942
4943 /* If there is enough input remaining. */
4944 if (DO_LARGE && (stream->input_position + LLOOK <= stream->avail_in))
4945 {
4946 if ((stream->input_position >= next_move_point) &&
4947 (ret = xd3_srcwin_move_point (stream, & next_move_point)))
4948 {
4949 return ret;
4950 }
4951
4952 linx = xd3_checksum_hash (& stream->large_hash, lcksum);
4953
4954 IF_DEBUG (xd3_verify_large_state (stream, inp, lcksum));
4955
4956 /* Note: To handle large checksum duplicates, this code should be rearranged to
4957 * resemble the small_match case more. But how much of the code can be truly
4958 * shared? The main difference is the need for xd3_source_extend_match to work
4959 * outside of xd3_string_match, in the case where inputs are identical. */
4960 if (unlikely (stream->large_table[linx] != 0))
4961 {
4962 /* the match_setup will fail if the source window has been decided and the
4963 * match lies outside it. You could consider forcing a window at this point
4964 * to permit a new source window. */
4965 xoff_t adj_offset =
4966 xd3_source_cksum_offset(stream,
4967 stream->large_table[linx] - HASH_CKOFFSET);
4968 if (xd3_source_match_setup (stream, adj_offset) == 0)
4969 {
4970 if ((ret = xd3_source_extend_match (stream)))
4971 {
4972 return ret;
4973 }
4974
4975 /* Update stream position. match_fwd is zero if no match. */
4976 if (stream->match_fwd > 0)
4977 {
4978 HANDLELAZY (stream->match_fwd);
4979 }
4980 }
4981 }
4982 }
4983
4984 /* Small matches. */
4985 if (DO_SMALL)
4986 {
4987 sinx = xd3_checksum_hash (& stream->small_hash, scksum);
4988
4989 /* Verify incremental state in debugging mode. */
4990 IF_DEBUG (xd3_verify_small_state (stream, inp, scksum));
4991
4992 /* Search for the longest match */
4993 if (unlikely (stream->small_table[sinx] != 0))
4994 {
4995 match_length = xd3_smatch (stream,
4996 stream->small_table[sinx],
4997 scksum,
4998 & match_offset);
4999 }
5000 else
5001 {
5002 match_length = 0;
5003 }
5004
5005 /* Insert a hash for this string. */
5006 xd3_scksum_insert (stream, sinx, scksum, stream->input_position);
5007
5008 /* Maybe output a COPY instruction */
5009 if (unlikely (match_length >= stream->min_match))
5010 {
5011 IF_DEBUG1 ({
5012 static int x = 0;
5013 DP(RINT "[target match:%d] <inp %u %u> <cpy %u %u> (-%d) [ %u bytes ]\n",
5014 x++,
5015 stream->input_position,
5016 stream->input_position + match_length,
5017 match_offset,
5018 match_offset + match_length,
5019 stream->input_position - match_offset,
5020 match_length);
5021 });
5022
5023 if ((ret = xd3_found_match (stream,
5024 /* decoder position */ stream->input_position,
5025 /* length */ match_length,
5026 /* address */ match_offset,
5027 /* is_source */ 0))) { return ret; }
5028
5029 /* Copy instruction. */
5030 HANDLELAZY (match_length);
5031 }
5032 }
5033
5034 /* The logic above prevents excess work during lazy matching by increasing min_match
5035 * to avoid smaller matches. Each time we advance stream->input_position by one, the minimum match
5036 * shortens as well. */
5037 if (stream->min_match > MIN_MATCH)
5038 {
5039 stream->min_match -= 1;
5040 }
5041
5042 updateone:
5043
5044 /* See if there are no more incremental cksums to compute. */
5045 if (stream->input_position + SLOOK == stream->avail_in)
5046 {
5047 goto loopnomore;
5048 }
5049
5050 /* Compute next RUN, CKSUM */
5051 if (DO_RUN) { NEXTRUN (inp[SLOOK]); }
5052 if (DO_SMALL) { SMALL_CKSUM_UPDATE (scksum, inp, SLOOK); }
5053 if (DO_LARGE && (stream->input_position + LLOOK < stream->avail_in)) { LARGE_CKSUM_UPDATE (lcksum, inp, LLOOK); }
5054 }
5055
5056 loopnomore:
5057 return 0;
5058}
5059#endif /* XD3_ENCODER */
5060#endif /* __XDELTA3_C_TEMPLATE_PASS__ */
Note: See TracBrowser for help on using the repository browser.